16-385	bryum1-t.jpg	bryum1-v.jpg	72	bryum1-h.jpg	163	<B><I>Bryum</i> species</b> with prostrate moss gametophyte and maturing sporophytic capsules.  The capsules are complex, dominating the body of the sporophyte.	Bryophyta, Bryales, gametophyte, sporophyte, moss	0.1	Lab02
16-386	bryum2-t.jpg	bryum2-v.jpg	59	bryum2-h.jpg	147	<B><I>Bryum</i> capsules</b> form the sporophyte. The moss gametophyte is prostrate and individual plants are inconspicuous.	Bryophyta, Bryales, gametophyte, sporophyte, moss	0.2	Lab02
16-386	polytrichum-t.jpg	polytrichum-v.jpg	91	polytrichum-h.jpg	209	<B><I>Polytrichum</i> species</b> with emergent erect gametophyte.  The sporophyte of this plant hydroids and leptoids -- moss analogs of xylem and phloem.	Bryophyta, Bryales, gametophyte, moss	0.3	Lab02
16-095	16-095t.jpg	16-095v.jpg	106	16-095h.jpg	533	<B><I>Mnium</i> antheridiaphore</b> with protective leaves and rhizoids. This moss contains elongated slender antheridia that are largely exposed on the elevated antheridophore.	Bryophyta, Bryales, antheridia	1	Lab02
16-094	16-094t.jpg	16-094v.jpg	249	16-094h.jpg	545	<B><I>Mnium</i> developing antheridia</b>. The antheridia are at a diversity of different developmental stages on the antheridiophore from early spermatogenesis to sperm cell maturation.	Bryophyta, Bryales, antheridia	2	Lab02
16-104	16-104t.jpg	16-104v.jpg	132	16-104h.jpg	538	<B><I>Mnium</i> archegoniophore</b> provides protective leaves and rhizoids amid the developing archegonia of this moss. Archegonia range from maturity (see egg cell on the left), to quite imature stages.	Bryophyta, Bryales, archegonia	3	Lab02
16-103	16-103t.jpg	16-103v.jpg	129	16-103h.jpg	715	<B><I>Mnium</i> archegonium</b>. Archegonia are highly elongated, with thick necks and elongated axial rows of numerous neck cells. This reflects a more primitive form of gametangia.	Bryophyta, Bryales, archegonia	4	Lab02
16-386	mnium-eggs-t.jpg	mnium-eggs-v.jpg	79	mnium-eggs-h.jpg	220	<B><I>Mnium</i> archegonia</b>. Two archegonia are evident here. The axial row, having begun degeneration, reflects a receptive egg. Note ventral canal cell in the right archegonium.	Bryophyta, Bryales, archegonia, gametophyte, moss	4.01	Lab02
16-386	mnium-egg-redo-t.jpg	mnium-egg-redo-v.jpg	82	mnium-egg-redo-h.jpg	228	<B><I>Mnium</i> archegonium</b> containing a receptive egg cell as viewed using differential interference contrast microscopy.	Bryophyta, Bryales, archegonia, gametophyte, moss	4.02	Lab02
16-386	mnium-egg-t.jpg	mnium-egg-v.jpg	82	mnium-egg-h.jpg	228	<B><I>Mnium</i> archegonium</b> containing a receptive egg cell.	Bryophyta, Bryales, archegonia, gametophyte, moss	4.03	Lab02
16-386	moss-liverwort-t.jpg	moss-liverwort-v.jpg	169	moss-liverwort-h.jpg	417	<B><I>Mnium</i> archegonium</b> containing a receptive egg cell.	Bryophyta, Bryales, Marchantiales, gametophyte, moss, thallose liverwort	4.1	Lab02
16-386	marchantia-gametophore-lawn-t.jpg	marchantia-gametophore-lawn-v.jpg	140	marchantia-gametophore-lawn-h.jpg	313	<B><I>Marchantia</i> thallus</b> with archegoniophores (lobed umbrellas) and antheridiophores (webbed umbrellas).	Bryophyta, Bryales, Marchantiales, gametophyte, archegoniophore, antheridiophore, thallose liverwort	4.2	Lab02
16-386	reboulia-t.jpg	reboulia-v.jpg	47	reboulia-h.jpg	131	<B><I>Reboulia</i> archegoniophores</b> appear largely similar to those of <I>Marchantia</i>.	Bryophyta, Bryales, Marchantiales, gametophyte, archegoniophore, thallose liverwort	4.21	Lab02
16-386	marchantia-gametophores-t.jpg	marchantia-gametophores-v.jpg	81	marchantia-gametophores-h.jpg	193	<B><I>Marchantia</i> thallus</b> with archegoniophores (lobed umbrellas) and antheridiophores (webbed umbrellas).	Bryophyta, Bryales, Marchantiales, gametophyte, archegoniophore, antheridiophore, thallose liverwort	4.3	Lab02
16-386	marchantia-gemma-t.jpg	marchantia-gemma-v.jpg	56	marchantia-gemma-h.jpg	143	<B><I>Marchantia</i> thallus</b> with gemma cups, contining the vegetative propagules called gemmae.	Bryophyta, Bryales, Marchantiales, gametophyte, archegoniophore, antheridiophore, thallose liverwort	4.4	Lab02
16-102	16-102t.jpg	16-102v.jpg	241	16-102h.jpg	642	<B><I>Marchantia</i> archegoniophore</b>. Archegonia at a range of developmental stages are evident on the underside of the archegoniophore.	Bryophyta, Marchantiales, archegoniophore	5	Lab02
16-093	16-093t.jpg	16-093v.jpg	208	16-093h.jpg	410	<B><I>Marchantia</i> mature antheridium</b>. The sperm cells form in developmental merophytes (derivatives of the same cell lineage). The antheridia are retained within the antheridiophore.	Bryophyta, Marchantiales, antheridia	5.5	Lab02
16-101	16-101t.jpg	16-101v.jpg	136	16-101h.jpg	608	<B><I>Marchantia</i> archegoniophore</b>. Immature archegonia through fertilized archegonia are evident on the underside of the archegoniophore.	Bryophyta, Marchantiales, archegoniophore	6	Lab02
16-100	16-100t.jpg	16-100v.jpg	102	16-100h.jpg	439	<B><I>Marchantia</i> developing archegonia</b>. A gradation of archegonial stages are evident on teh underside of this archegoniophore. Note immature ventral canal cell and neck canal mother cell (right).	Bryophyta, Marchantiales, archegonia	7	Lab02
16-098	16-098t.jpg	16-098v.jpg	175	16-098h.jpg	2179	<B><I>Marchantia</i> archegonial stages</b>. Note the archegonial initial to the left, 2-4 cell stage, to a fertilized archegonium on the right. Of what advantage would this strategy be?	Bryophyta, Marchantiales, archegonia	8	Lab02
16-099	16-099t.jpg	16-099v.jpg	220	16-099h.jpg	442	<B><I>Marchantia</i> mature archegonium</b>. Note the large egg cell, ventral canal cell, neck canal cells and axial row. Prior to fertilization, the cells intervening between the cap cell and egg break down.	Bryophyta, Marchantiales, archegonia	9	Lab02
16-097	16-097t.jpg	16-097v.jpg	87	16-097h.jpg	331	<B><I>Marchantia</i> archegonial stages</b>. Note archegonial row initial (left). The central archegonium appears ready for fertilization.	Bryophyta, Marchantiales, archegonia	10	Lab02
16-092	16-092t.jpg	16-092v.jpg	222	16-092h.jpg	442	<B><I>Marchantia</i> young sporophyte</b>. This archegonium has been recently fertilized and is at about the 64 celled stage.  The polarity of the sporophyte is poorly distinguished.	Bryophyta, Marchantiales, archegonia	11	Lab02
16-096	16-096t.jpg	16-096v.jpg	285	16-096h.jpg	845	<B><I>Marchantia</i> mature archegonium</b>. Note the large egg cell, ventral canal cell, and obliquely sectioned neck canal cells. A rhizoid is provides some protection. (Nomarski interference contrast microscopy)	Bryophyta, Marchantiales, archegonium	11	Lab02
16-091	16-091t.jpg	16-091v.jpg	257	16-091h.jpg	485	<B><I>Marchantia</i> young sporophyte</b>. This sporophyte is still located within the archegonium. Note the degerate material in the archegonial neck through which the sperm entered.	Bryophyta, Marchantiales, sporophyte	12	Lab02
16-090	16-090t.jpg	16-090v.jpg	133	16-090h.jpg	484	<B><I>Marchantia</i> young sporophyte</b>. The foot, seta and developing capsule differentiate early in this differentiating sporophyte.	Bryophyta, Marchantiales, sporophyte	13	Lab02
16-089	16-089t.jpg	16-089v.jpg	111	16-089h.jpg	403	<B><I>Marchantia</i> young sporophyte</b>. The foot, seta and developing capsule are evident in this differentiating sporophyte.	Bryophyta, Marchantiales, sporophyte	14	Lab02
16-088	16-088t.jpg	16-088v.jpg	163	16-088h.jpg	558	<B><I>Marchantia</i> maturing sporophyte</b>. Spores are aligned parallel to elators within the capsule, shown here prior to their separation.	Bryophyta, Marchantiales, sporophyte	15	Lab02
16-087	16-087t.jpg	16-087v.jpg	103	16-087h.jpg	474	<B><I>Marchantia</i> mature sporophyte</b>. The capsule is filled with spores and elators that aid dissemination. These hang, pendulous from the archegoniophore.	Bryophyta, Marchantiales, sporophyte	16	Lab02
16-085	16-085t.jpg	16-085v.jpg	81	16-085h.jpg	631	<B>Kidstone and Gwynne-Vaughn</b> examining the fossils of the Rhynie chert, where <I>Rhynia</i> and many of the Rhyniophytes were discovered.	Early Fossil Hunters	16.1	Lab04
16-083	16-083t.jpg	16-083v.jpg	89	16-083h.jpg	441	<B><I>Cooksonia</i> and <I>Rhynia</i></b> in a diorama of life 400 mya. Milwaukee Public Museum.	Museum, Devonian, Rhyniophyta	16.2	Lab04
16-086	16-086t.jpg	16-086v.jpg	68	16-086h.jpg	271	<B>Origin of Alternation of Generations</b> is depicted in these two diagrams illustrating the isomorphic (homologous) and transformation (antithetic) models.	Alternation of Generations	16.6	Lab04
16-080	16-080t.jpg	16-080v.jpg	110	16-080h.jpg	357	<B><I>Lycopodium lucidulum</i></b> shows indeterminate growth on all axes.  Interrupted reproductive regions constitute poorly defined strobilar regions.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.0105	Lab06
16-076	16-076t.jpg	16-076v.jpg	102	16-076h.jpg	184	<B><I>Lycopodium lucidulum</i></b> showing interrupted strobilus, sporophylls nearly identical to microphylls. A propagule known as a bulbil is also visible.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.011	Lab06
16-075	16-075t.jpg	16-075v.jpg	163	16-075h.jpg	281	<B><I>Lycopodium annotinum</i></b> shows two microphyll morphologies, terminal strobili and determinate growth. Vilas County, Wisconsin.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.012	Lab06
16-071	16-071t.jpg	16-071v.jpg	193	16-071h.jpg	353	<B><I>Lycopodium obscurum</i></b> shows two microphyll morphologies, overtopped strobili. Vilas County, Wisconsin.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.013	Lab06
16-073	16-073t.jpg	16-073v.jpg	88	16-073h.jpg	293	<B><I>Lycopodium clavatum</i></b> shows three microphyll morphologies, multiple strobili and relatively great specialization. Vilas County, Wisconsin.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.014	Lab06
16-078	16-078t.jpg	16-078v.jpg	241	16-078h.jpg	442	<B><I>Lycopodium</i> sp.</b> in Costa Rica, shows typical habit of an epiphytic lycopod.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.015	Lab06
16-077	16-077t.jpg	16-077v.jpg	196	16-077h.jpg	337	<B><I>Lycopodium squarrosum</i></b> showing epiphytic, tropical habit. Photo taken at Australian National Botanical Garden, Canberra.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.016	Lab06
16-079	16-079t.jpg	16-079v.jpg	148	16-079h.jpg	272	<B><I>Lycopodium phlegmaria</i></b> showing epiphytic, tropical habit. Photo taken at Australian National Botanical Garden, Canberra.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.017	Lab06
16-070	16-070t.jpg	16-070v.jpg	107	16-070h.jpg	343	<B><I>Lycopodium adpressum</i></b> apical meristem with apical cell.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.02	Lab06
16-072	16-072t.jpg	16-072v.jpg	166	16-072h.jpg	341	<B><I>Lycopodium inundatum</i> rhizome</b> with conspicuous leaf traces, exarch maturation.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.031	Lab06
16-074	16-074t.jpg	16-074v.jpg	178	16-074h.jpg	558	<B><I>Lycopodium clavatum</i></b> rhizome cross section showing an impressive plectostele, leaf traces and sclerified cortical sheath.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.032	Lab06
16-069	16-069t.jpg	16-069v.jpg	195	16-069h.jpg	580	<B><I>Lycopodium obscurum</i></b> plectostele.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.033	Lab06
16-061	16-061t.jpg	16-061v.jpg	125	16-061h.jpg	410	<B><I>Lycopodium lucidulum</i> bulbil</b> viewed in longitudinal section, showing subtending leaf, as well as shoot and root apices.	Lycophyta, Lycopodiales, vegetative, sporophyte	17.04	Lab06
16-059	16-059t.jpg	16-059v.jpg	109	16-059h.jpg	2109	<B><I>Lycopodium</i> sporangial initials</b> are characteristic of the eusporangiate development. Note the axial origin of the sporangium.	Lycophyta, Lycopodiales, sporangial ontogeny	18	Lab07
16-058	16-058t.jpg	16-058v.jpg	111	16-058h.jpg	1830	<B><I>Lycopodium</i> sporangial development</b>. This eusporangium is in early development. Note the origin of layering -- an early stage in formation of the sporangial wall.	Lycophyta, Lycopodiales, sporangial ontogeny	18.1	Lab07
16-057	16-057t.jpg	16-057v.jpg	213	16-057h.jpg	1664	<B><I>Lycopodium</i> later sporangial development</b>. Sporogenous tissue becomes conspicuous by greater cytoplasmic density and accumulation of dense nuclei.	Lycophyta, Lycopodiales, sporogenesis	19	Lab07
16-056	16-056t.jpg	16-056v.jpg	177	16-056h.jpg	1144	<B><I>Lycopodium</i> late sporangial development</b>. Sporogenous tissue is quite well defined at this stage. The thick walls surrounding developing sporocytes is characteristic.	Lycophyta, Lycopodiales, sporogenesis	20	Lab07
16-055	16-055t.jpg	16-055v.jpg	102	16-055h.jpg	1667	<B><I>Lycopodium clavatum</i> sporogenesis I</b>. Sporocytes having completed meiosis are now spores, still present in tetrads. Note tapetum and thickness of sporangial wall.	Lycophyta, Lycopodiales, sporogenesis	21	Lab07
16-054	16-054t.jpg	16-054v.jpg	84	16-054h.jpg	1506	<B><I>Lycopodium clavatum</i> sporogenesis II</b>. Post-meiotic spores remain in tetrads in this image. Tapetal cells are found among the sporocytes at this stage.	Lycophyta, Lycopodiales, sporogenesis	22	Lab07
16-053	16-053t.jpg	16-053v.jpg	102	16-053h.jpg	1587	<B><I>Lycopodium clavatum</i> sporogenesis III</b>. Spores separate and exine walls mature at this stage. Tapetal cells found among the sporocytes are beginning to break down.	Lycophyta, Lycopodiales, sporogenesis	23	Lab07
16-052	16-052t.jpg	16-052v.jpg	116	16-052h.jpg	1968	<B><I>Lycopodium clavatum</i> sporogenesis IV</b>. Exine completes maturation, trilete marks occasionally evident. Tapetal cells, found among the sporocytes, continue to break down.	Lycophyta, Lycopodiales, sporogenesis	24	Lab07
16-051	16-051t.jpg	16-051v.jpg	116	16-051h.jpg	1534	<B><I>Lycopodium</i> mature eusporangium</b>. Spores increase in density as they accumulate food stores.  Tapetum breaks down in preparation for dehiscence. Note laminar location of sporangial attachment.	Lycophyta, Lycopodiales, sporangium	25	Lab07
16-050	16-050t.jpg	16-050v.jpg	258	16-050h.jpg	1938	<B><I>Lycopodium lucidulum</i> mature eusporangium</b>. Note the axillary location of sporangial attachment.  This is characteristic of some of the less derived of the Lycopodiaceae.	Lycophyta, Lycopodiales, sporangium	26	Lab07
16-049	16-049t.jpg	16-049v.jpg	129	16-049h.jpg	1990	<B><I>Lycopodium obscurum</i> mature eusporangium</b>. The laminar location of sporangial attachment on the sporophyll is characteristic of more advanced species.	Lycophyta, Lycopodiales, sporangium	27	Lab07
16-060	16-060t.jpg	16-060v.jpg	193	16-060h.jpg	347	<B><I>Phylloglossum drummondii</i> tuber and shoot apex.</b> This diminutive relative of <I>Lycopodium</i> is quite rare. Slide made at University of Oklahoma.	Lycophyta, Lycopodiales, tuber	28	Lab07
16-048	16-048t.jpg	16-048v.jpg	299	16-048h.jpg	1878	<B><I>Phylloglossum drummondii</i> stobilus</b>. This image of this unusual plant shows a longitudinal section of the cone with a wide range of stages of sporogenesis.	Lycophyta, Lycopodiales, sporangia	29	Lab07
16-047	16-047t.jpg	16-047v.jpg	103	16-047h.jpg	1912	<B><I>Lycopodium</i> gametophyte with mature antheridia</b>, which are are embedded in the gametophyte.  Antheridia are typically on the underside of the gametophyte.	Lycophyta, Lycopodiales, gametophyte, antheridia	30	Lab07
16-046	16-046t.jpg	16-046v.jpg	130	16-046h.jpg	1975	<B><I>Lycopodium</i> gametophyte with endophytic fungus</b>, characteristic of the slowest growing Lycopod gametophytes. Gametophytes of some species may require up to 7 years to mature.	Lycophyta, Lycopodiales, gametophyte	31	Lab07
16-044	16-044t.jpg	16-044v.jpg	128	16-044h.jpg	2030	<B><I>Lycopodium</i> gametophyte with archegonia</b> show the onset of the sexual phase of this long-lived plant.  Note the axial row present in the archegonial neck.	Lycophyta, Lycopodiales, gametophyte, archegonium, embryogenesis	32	Lab07
16-045	16-045t.jpg	16-045v.jpg	120	16-045h.jpg	2027	<B><I>Lycopodium</i> gametophyte with mature archegonia</b> showing the axial row in the archegonial neck, ventral canal cell and interior egg cell.	Lycophyta, Lycopodiales, gametophyte, archegonium	33	Lab07
16-043	16-043t.jpg	16-043v.jpg	209	16-043h.jpg	1658	<B><I>Lycopodium</i> embryogenesis</b> shows a high diversity of different embryogenetic pathways, which is presumed to be a primitive characteristic. The classical embryo is endoscopic, with the suspensor located under the archegonial neck and the shoot emerging laterally.	Lycophyta, Lycopodiales, embryogenesis	34	Lab07
16-lycopo	lycopodium-1-t.jpg	lycopodium-1-v.jpg	180	lycopodium-1-h.jpg	740	<B><I>Lycopodium</i> embryogenesis</b> shows a  diversity of embryogenetic pathways, a presumed primitive characteristic. From Wardlaw (1955).	Lycophyta, Lycopodiales, embryogenesis	34	Lab07
16-042	16-042t.jpg	16-042v.jpg	125	16-042h.jpg	2025	<B><I>Lycopodium</i> embryogenesis</b> showing young leaves of this plant. The embryo is endoscopic, with suspensor located under archegonial neck and shoot emerging laterally.	Lycophyta, Lycopodiales, embryogenesis	35	Lab07
16-lycopo	lycopodium-2-t.jpg	lycopodium-2-v.jpg	174	lycopodium-2-h.jpg	669	<B>Embryogenesis in <I>Lycopodium cernuum</i> & <I>L. laterale</i></b> showing young leaves of this plant. From Wardlaw (1955).	Lycophyta, Lycopodiales, embryogenesis	35	Lab07
16-067	16-067t.jpg	16-067v.jpg	112	16-067h.jpg	366	<B><I>Selaginella krausiana</i> anisotomous branching</b>. Although the shoot apex undergoes dichotomous branching, overtopping results in anisotomy and a pseudomonopodial appearance in the plant habit.	Lycophyta, Selaginellales, shoot apex, dichotomous branching	35.01	Lab06
16-041	16-041t.jpg	16-041v.jpg	243	16-041h.jpg	1726	<B><I>Selaginella</i> shoot apex</b>. Branching of the apex is dichotomous, but one axis tends to overtop the other (anisotomous) resulting in pseudomonopodial branching. The vascular cylinder is suspended by trabeculae in mature regions of the axis.	Lycophyta, Selaginellales, shoot apex, dichotomous branching	35.02	Lab06
16-066	16-066t.jpg	16-066v.jpg	98	16-066h.jpg	407	<B><I>Selaginella</i> apical meristem</b> with apical cell at the tip. Note leaf primordia and young leaves.	Lycophyta, Selaginellales, vegetative, sporophyte	35.51	Lab06
16-064	16-064t.jpg	16-064v.jpg	123	16-064h.jpg	399	<B><I>Selaginella</i> rhizome</b>. Note meristeles are located in schizogenous chambers within the stem.	Lycophyta, Selaginellales, vegetative, sporophyte	35.52	Lab06
16-065	16-065t.jpg	16-065v.jpg	126	16-065h.jpg	370	<B><I>Selaginella</i> rhizome</b> showing a meristele with a plate of xylem. Note trabeculae and Casparian strips indicative of endodermis.	Lycophyta, Selaginellales, vegetative, sporophyte	35.53	Lab06
16-063	16-063t.jpg	16-063v.jpg	81	16-063h.jpg	272	<B><I>Selaginella</i> root</b> with two vascular bundles, presumably close to a dichotomy.	Lycophyta, Selaginellales, vegetative, sporophyte	35.57	Lab06
16-068	16-068t.jpg	16-068v.jpg	148	16-068h.jpg	402	<B><I>Selaginella</i> root</b> with two vascular bundles, presumably close to a dichotomy.	Lycophyta, Selaginellales, vegetative, sporophyte	35.58	Lab06
16-062	16-062t.jpg	16-062v.jpg	127	16-062h.jpg	385	<B><I>Selaginella</i> rhizophore</b> resembles both stems and roots to some degree. Created by an angle meristem in dichotomies, these are enigmatic organs.	Lycophyta, Selaginellales, vegetative, sporophyte	35.59	Lab06
16-037	16-037t.jpg	16-037v.jpg	209	16-037h.jpg	356	<B><I>Selaginella</i> strobilar axis</b> with adjacent newly initiated and maturing megasporangium and ligule.	Lycophyta, Selaginellales, megasporangium	37	Lab07
16-038	16-038t.jpg	16-038v.jpg	96	16-038h.jpg	349	<B><I>Selaginella</i> microsporangium</b> within a microsporophyll.  A ligule is quite conspicuous subtending the microsporangium.	Lycophyta, Selaginellales, microsporangium	38	Lab07
16-040	16-040t.jpg	16-040v.jpg	128	16-040h.jpg	2339	<B><I>Selaginella</i> microsporangium</b> with numerous microspores within.  Note the layering of the eusporangium.  Does this appear to be close to dehiscence?	Lycophyta, Selaginellales, microsporangium	39	Lab07
16-039	16-039t.jpg	16-039v.jpg	137	16-039h.jpg	399	<B><I>Selaginella</i> microsporangium</b> and microspores.	Lycophyta, Selaginellales, microsporangium	40	Lab07
16-036	16-036t.jpg	16-036v.jpg	170	16-036h.jpg	286	<B><I>Selaginella</i> young megaspores</b> within a megasporangium.  A ligule is quite conspicous subtending the megasporangium.	Lycophyta, Selaginellales, megasporangium	41	Lab07
16-035	16-035t.jpg	16-035v.jpg	185	16-035h.jpg	329	<B><I>Selaginella</i> young megaspores</b> within a megasporangium.	Lycophyta, Selaginellales, megasporangium	42	Lab07
16-034	16-034t.jpg	16-034v.jpg	60	16-034h.jpg	246	<B><I>Selaginella</i> young megaspores</b> within a megasporangium.	Lycophyta, Selaginellales, megasporangium	43	Lab07
16-033	16-033t.jpg	16-033v.jpg	250	16-033h.jpg	440	<B><I>Selaginella</i> megaspores</b> are evident in two adjacent megasporangia. Note the velum and sporophylls.	Lycophyta, Selaginellales, megasporangium	44	Lab07
16-032	16-032t.jpg	16-032v.jpg	146	16-032h.jpg	461	<B><I>Selaginella</i> megaspores</b> in the megasporangium.  Microgametogenesis has progressed to near maturity. It is unclear whether the trilete mark has split, but it may have already germinated.	Lycophyta, Selaginellales, megasporangium	45	Lab07
16-selagi	selaginella-1-t.jpg	selaginella-1-v.jpg	139	selaginella-1-h.jpg	511	<B>Embryogenesis in <I>Selaginella</i></b> from Wardlaw (1955).	Lycophyta, Selaginellales, embryogenesis	45.1	Lab07
16-selagi	selaginella-2-t.jpg	selaginella-2-v.jpg	143	selaginella-2-h.jpg	613	<B>Embryogenesis in <I>Selaginella</i></b> from Wardlaw (1955).	Lycophyta, Selaginellales, embryogenesis	45.2	Lab07
16-selagi	selaginella-3-t.jpg	selaginella-3-v.jpg	132	selaginella-3-h.jpg	510	<B>Embryogenesis in <I>Selaginella</i></b> from Wardlaw (1955).	Lycophyta, Selaginellales, embryogenesis	45.3	Lab07
16-selagi	selaginella-4-t.jpg	selaginella-4-v.jpg	162	selaginella-4-h.jpg	686	<B>Embryogenesis in <I>Selaginella</i></b> from Wardlaw (1955).	Lycophyta, Selaginellales, embryogenesis	45.4	Lab07
16-031	16-031t.jpg	16-031v.jpg	198	16-031h.jpg	344	<B><I>Isoetes storkii</i> plant</b> in Laguna de Po?s in Costa Rica. Photo by Norman Boke.	Lycophyta, Isoetales, plant habit	46	Lab08
16-030	16-030t.jpg	16-030v.jpg	94	16-030h.jpg	317	<B><I>Isoetes storkii</i> in Laguna de Po?s</b> in Costa Rica. Photo by Norman Boke.	Lycophyta, Isoetales, plant habit	47	Lab08
16-029	16-029t.jpg	16-029v.jpg	157	16-029h.jpg	535	<B><I>Isoetes storkii</i> in Laguna de Po?s</b> in Costa Rica. Photo by Norman Boke.	Lycophyta, Isoetales, plant habit	48	Lab08
16-028	16-028t.jpg	16-028v.jpg	328	16-028h.jpg	616	<B><I>Isoetes storkii</i> found in nature</b>. Roy Lent holds a species of <I>Isoetes</i> over the water in Laguna de Po?s in Costa Rica. Photo by Norman Boke.	Lycophyta, Isoetales, plant habit	49	Lab08
16-027	16-027t.jpg	16-027v.jpg	441	16-027h.jpg	899	<B><I>Isoetes</i> median saggital section</b> showing microphylls, apical meristem, anchor-shaped vascular core and traces (leaf and root).	Lycophyta, Isoetales, shoot axis	50	Lab08
16-026	16-026t.jpg	16-026v.jpg	174	16-026h.jpg	768	<B><I>Isoetes</i> median saggital section</b> showing surmounting microphylls, apical meristem, anchor-shaped vascular core (characteristic of a sagittal section and traces (leaf and root).	Lycophyta, Isoetales, shoot axis, root apex	51	Lab08
16-025	16-025t.jpg	16-025v.jpg	382	16-025h.jpg	666	<B><I>Isoetes</i> median frontal section</b> showing surmounting microphylls, apical meristem, vascular core and traces (leaf and root). Note prismatic zone.	Lycophyta, Isoetales, shoot axis	52	Lab08
16-024	16-024t.jpg	16-024v.jpg	372	16-024h.jpg	695	<B><I>Isoetes</i> corm in longitudinal section</b> showing the vascular attachment of the roots and their endogenous origin from the root apical region from the central vascular core.	Lycophyta, Isoetales	53	Lab08
16-023	16-023t.jpg	16-023v.jpg	198	16-023h.jpg	706	<B><I>Isoetes</i> corm in cross section</b>. The protostele of this plant is indeed unusually loose. A unifacial cambium forms parenchyma cells and some xylem tracheids.	Lycophyta, Isoetales	54	Lab08
16-022	16-022t.jpg	16-022v.jpg	185	16-022h.jpg	589	<B><I>Isoetes</i> corm in cross section</b>. This is the basal portion of the corm showing diverging root traces.	Lycophyta, Isoetales	55	Lab08
16-021	16-021t.jpg	16-021v.jpg	188	16-021h.jpg	644	<B><I>Isoetes</i> corm in cross section</b>. Note the unifacial cambium creating the prismatic zone. The cambium primarily gives rise to parenchyma.	Lycophyta, Isoetales	56	Lab08
16-020	16-020t.jpg	16-020v.jpg	162	16-020h.jpg	663	<B><I>Isoetes</i> corm in cross section</b>. This unusual corm had three lobes.  The center shows its Y-shaped furrow.	Lycophyta, Isoetales	57	Lab08
16-019	16-019t.jpg	16-019v.jpg	413	16-019h.jpg	842	<B><I>Isoetes</i> corm viewed by basal section</b> showing the ranked rhizotaxis of the roots. Although the roots arise endogenously, it is unusual to have such regular spacings.	Lycophyta, Isoetales, rhizotaxis	58	Lab08
16-018	16-018t.jpg	16-018v.jpg	288	16-018h.jpg	541	<B><I>Isoetes</i> ligule in cross section</b> is present above the sporangium.  Its function is still unclear, even though it is considered to be a characteristic structure of the heterosporous lycopods.	Lycophyta, Isoetales, shoot axis	59	Lab08
16-017	16-017t.jpg	16-017v.jpg	102	16-017h.jpg	316	<B><I>Isoetes</i> root cross section</b>. This unusual tubular structure with an eccentric positioning of the trace is also characteristic of the roots of the extinct plant <I>Stigmaria</i>.	Lycophyta, Isoetales, Stigmarian root	60	Lab08
16-016	16-016t.jpg	16-016v.jpg	108	16-016h.jpg	389	<B><I>Isoetes</i> root cross section</b>. This possesses an almost trabecular connection of the root trace.  The unusual tubular structure resembles the leaves in some ways.	Lycophyta, Isoetales, Stigmarian root	61	Lab08
16-015	16-015t.jpg	16-015v.jpg	127	16-015h.jpg	280	<B><I>Isoetes</i> leaf cross section</b> showing the four-chamber nature of the distal part of the leaf. Typical of a microphyllous plant, there is a single trace in the leaf.	Lycophyta, Isoetales, leaf	62	Lab08
16-014	16-014t.jpg	16-014v.jpg	345	16-014h.jpg	671	<B><I>Isoetes</i> median longitudinal section</b> showing the vascular supply to the maturing sporophylls very nicely. The apical meristem surmounts the vascular core that is located beneath.  Note the conspicuous loosely-organized primary xylem.	Lycophyta, Isoetales, shoot axis	63	Lab08
16-013	16-013t.jpg	16-013v.jpg	169	16-013h.jpg	726	<B><I>Isoetes</i> median longitudinal section</b> showing immature microphylls and apical meristem. The vascular core is located beneath, with primary xylem conspicuous in this view.	Lycophyta, Isoetales, shoot axis	64	Lab08
16-012	16-012t.jpg	16-012v.jpg	324	16-012h.jpg	695	<B><I>Isoetes</i> median longitudinal section</b> showing an early eusporangium developing on the surface of the sporophyll and the apical meristem closeby. Sporophylls protect the apical region.	Lycophyta, Isoetales, shoot axis	65	Lab08
16-011	16-011t.jpg	16-011v.jpg	349	16-011h.jpg	648	<B><I>Isoetes</i> median longitudinal section</b> showing maturing sporophylls, the apical meristem, and the underlying corm, with its unusual vascular cambium region.	Lycophyta, Isoetales, shoot axis	66	Lab08
16-010	16-010t.jpg	16-010v.jpg	316	16-010h.jpg	568	<B><I>Isoetes</i> microsporangium</b> containing maturing microspores that are located among the trabecular process of the sporangium.	Lycophyta, Isoetales, microsporangium	67	Lab08
16-009	16-009t.jpg	16-009v.jpg	330	16-009h.jpg	577	<B><I>Isoetes</i> microsporangium</b> containing maturing microspores that are located among the trabecular process of the sporangium.	Lycophyta, Isoetales, microsporangium	68	Lab08
16-008	16-008t.jpg	16-008v.jpg	284	16-008h.jpg	548	<B><I>Isoetes</i> megasporophyll with ligule</b>. Although the function of the ligule is not clear, it is characteristic and contains an endodermal layer, suggesting secretory involvement. Many megaspores are evident.	Lycophyta, Isoetales, megasporangium	69	Lab08
16-007	16-007t.jpg	16-007v.jpg	232	16-007h.jpg	391	<B><I>Isoetes</i> megasporangium</b> containing maturing megaspores, prior to the filling of the cytoplasm.	Lycophyta, Isoetales, megasporangium	70	Lab08
16-006	16-006t.jpg	16-006v.jpg	131	16-006h.jpg	493	<B><I>Isoetes</i> megasporangium</b> containing maturing megaspores.  In <I>Isoetes</i> the spores often have multiple nuclei, indicating that these are in early megagametogenesis.	Lycophyta, Isoetales, megasporangium, microsporangium	71	Lab08
16-005	16-005t.jpg	16-005v.jpg	181	16-005h.jpg	339	<B><I>Isoetes</i> megasporangium</b> containing megaspores with early stage megagametophytes. Retension and provisioning of the megaspores shows increased of gametophytic tissues.	Lycophyta, Isoetales, megasporangium	72	Lab08
16-004	16-004t.jpg	16-004v.jpg	91	16-004h.jpg	311	<B><I>Isoetes</i> megagametophyte</b> soon after germination. Swelling of gametophytic tissue occurs along the trilete mark. At this location and along these grooves, archegonia form that will be fertilized by motile sperm, if present.	Lycophyta, Isoetales, gametogenesis	73	Lab08
16-003	16-003t.jpg	16-003v.jpg	146	16-003h.jpg	252	<B><I>Isoetes</i> embryogenesis</b>. Inclined exoscopic embryo gives rise to shoot, leaf, root and foot. Shoot emerges through wall of the gametophyte to establish the young sporophyte. From Wardlaw (1955), p. 119.	Lycophyta, Isoetales, embryogenesis	74	Lab08
16-isoete	isoetes-t.jpg	isoetes-v.jpg	130	isoetes-h.jpg	505	<B>Embryogenesis in <I>Isoetes</i></b> from Wardlaw (1955).	Lycophyta, Isoetales, embryogenesis	74	Lab08
16-equisetum	equisetum-t.jpg	equisetum-v.jpg	23	equisetum-h.jpg	23	<B><I>Equisetum hyemale</i></b> reproductive/vegetative shoot. An intermediate morphological pattern. Courtesy Cals Plant-of-the-Week	Sphenophyta, Equisetales, sporophyte	74.5	Lab09
16-002	16-002t.jpg	16-002v.jpg	46	16-002h.jpg	152	<B><I>Equisetum arvense</i></b> reproductive and vegetative shoots. Sporangiophores are readily visible in the strobilus, as is the basal annulus. Photo taken in May in Bayside, Wisconsin	Sphenophyta, Equisetales, sporophyte	75	Lab09
16-001	16-001t.jpg	16-001v.jpg	62	16-001h.jpg	198	<B><I>Equisetum arvense</i></b> with dimorphic aerial shoots. Reproductive shoots with strobili reach maturity as vegetative axes are becoming conspicuous. Photo taken in May in Bayside, Wisconsin	Sphenophyta, Equisetales, sporophyte	76	Lab09
16-211	16-211t.jpg	16-211v.jpg	52	16-211h.jpg	113	<B><I>Equisetum arvense</i></b>. Young aerial stem with elongating lateral branches piercing base of microphylls	Sphenophyta, Equisetales, sporophyte	80	Lab09
16-210	16-210t.jpg	16-210v.jpg	77	16-210h.jpg	168	<B><I>Equisetum giganteum</i></b> in Costa Rica, co-starring Roy Lent.	Sphenophyta, Equisetales, sporophyte	81	Lab09
16-209	16-209t.jpg	16-209v.jpg	78	16-209h.jpg	287	<B><I>Equisetum arvense</i> aerial stem</b> cross-section. This is the sterile stem, showing carinal and vallecular canals, ribs.	Sphenophyta, Equisetales, sporophyte	82	Lab09
16-208	16-208t.jpg	16-208v.jpg	41	16-208h.jpg	172	<B><I>Equisetum arvense</i> shoot apex</b> cross section of apex and lateral branches, showing cortical ribs and fused microphyllous leaves.	Sphenophyta, Equisetales, sporophyte	83	Lab09
16-207	16-207t.jpg	16-207v.jpg	67	16-207h.jpg	229	<B><I>Equisetum intermedium</i> stem</b> showing highly silicified rib.	Sphenophyta, Equisetales, sporophyte	84	Lab09
16-206	16-206t.jpg	16-206v.jpg	34	16-206h.jpg	149	<B><I>Equisetum arvense</i> stem</b> cross section at the node, showing lateral branch apices located opposite the leaf midribs.	Sphenophyta, Equisetales, sporophyte	85	Lab09
16-205	16-205t.jpg	16-205v.jpg	76	16-205h.jpg	247	<B><I>Equisetum hyamale</i> vascular bundle</b> in rhizome.	Sphenophyta, Equisetales, sporophyte	86	Lab09
16-204	16-204t.jpg	16-204v.jpg	48	16-204h.jpg	174	<B><I>Equisetum</i> stem</b> with carinal and vallecular canals.	Sphenophyta, Equisetales, sporophyte	87	Lab09
16-203	16-203t.jpg	16-203v.jpg	44	16-203h.jpg	150	<B><I>Equisetum intermedium</i> vascular bundle</b> in aerial stem.  Note location of the endodermis.	Sphenophyta, Equisetales, sporophyte	88	Lab09
16-202	16-202t.jpg	16-202v.jpg	41	16-202h.jpg	147	<B><I>Equisetum hyamale</i> endodermis</b> with conspicuous Casparian strips.	Sphenophyta, Equisetales, sporophyte	89	Lab09
16-201	16-201t.jpg	16-201v.jpg	85	16-201h.jpg	311	<B><I>Equisetum arvense</i> nodal region</b>. Note interruption of vallecular canals, pith opening.	Sphenophyta, Equisetales, sporophyte	90	Lab09
16-200	16-200t.jpg	16-200v.jpg	62	16-200h.jpg	242	<B><I>Equisetum</i> branch</b> before emergence through the leaf sheath, as viewed in median longitudinal section.	Sphenophyta, Equisetales, sporophyte	91	Lab09
16-199	16-199t.jpg	16-199v.jpg	51	16-199h.jpg	200	<B><I>Equisetum intermedium</i> young root</b>, showing canal system and central vasculature.	Sphenophyta, Equisetales, sporophyte	92	Lab09
16-198	16-198t.jpg	16-198v.jpg	70	16-198h.jpg	266	<B><I>Equisetum intermedium</i> older root vasculature</b>	Sphenophyta, Equisetales, sporophyte	93	Lab09
16-197	16-197t.jpg	16-197v.jpg	50	16-197h.jpg	193	<B><I>Equisetum intermedium</i> vascular bundle</b>, showing carinal canal, protoxylem, metaxylem, phloem.	Sphenophyta, Equisetales, sporophyte	94	Lab09
16-196	16-196t.jpg	16-196v.jpg	62	16-196h.jpg	225	<B><I>Equisetum  intermedium</i> another root</b>	Sphenophyta, Equisetales, sporophyte	95	Lab09
16-195	16-195t.jpg	16-195v.jpg	48	16-195h.jpg	174	<B><I>Equisetum intermedium</i> lateral root formation</b>. Note the prominent apical cell and relative position of different cell layers.	Sphenophyta, Equisetales, sporophyte	96	Lab09
16-194	16-194t.jpg	16-194v.jpg	76	16-194h.jpg	313	<B><I>Equisetum</i> root apex</b>, showing apical cell, root axis and root cap.	Sphenophyta, Equisetales, sporophyte	97	Lab09
16-193	16-193t.jpg	16-193v.jpg	47	16-193h.jpg	194	<B><I>Equisetum</i> root apex</b> shown at higher magnification, showing the four cutting faces of apical cell. Its derivatives are evident in root axis and root cap.	Sphenophyta, Equisetales, sporophyte	98	Lab09
16-192	16-192t.jpg	16-192v.jpg	48	16-192h.jpg	202	<B><I>Equisetum</i> shoot apex</b>, showing apical cell, merophytes and pattern of leaf initiation.	Sphenophyta, Equisetales, sporophyte	99	Lab09
16-191	16-191t.jpg	16-191v.jpg	58	16-191h.jpg	202	<B><I>Equisetum</i> sporangium</b> with mature spores and elators. Note structure of endothecial thickenings and cell layers in sporangial wall.	Sphenophyta, Equisetales, sporophyte	100	Lab09
16-190	16-190t.jpg	16-190v.jpg	66	16-190h.jpg	274	<B><I>Equisetum</i> sporangiophore</b>, innervated with central vascular bundle, visible here.	Sphenophyta, Equisetales, sporophyte	101	Lab09
16-189	16-189t.jpg	16-189v.jpg	32	16-189h.jpg	146	<B><I>Equisetum</i> gametophyte</b> with antheridia. Note rhizoids and marginal placement of gametangia.	Sphenophyta, Equisetales, gametophyte	102	Lab09
16-188	16-188t.jpg	16-188v.jpg	70	16-188h.jpg	262	<B><I>Equisetum</i> gametophyte</b> showing the organization of the prothallus tissue.	Sphenophyta, Equisetales, gametophyte	103	Lab09
16-187	16-187t.jpg	16-187v.jpg	54	16-187h.jpg	212	<B><I>Equisetum</i> antheridium</b> at near maturity.	Sphenophyta, Equisetales, gametophyte	104	Lab09
16-186	16-186t.jpg	16-186v.jpg	54	16-186h.jpg	210	<B><I>Equisetum</i> antheridium</b> at near maturity.	Sphenophyta, Equisetales, gametophyte	105	Lab09
16-185	16-185t.jpg	16-185v.jpg	62	16-185h.jpg	246	<B><I>Equisetum</i> antheridium</b> nearly at  maturity.</b>	Sphenophyta, Equisetales, gametophyte	106	Lab09
16-184	16-184t.jpg	16-184v.jpg	54	16-184h.jpg	240	<B><I>Equisetum</i> antheridium</b> near maturity. Note the single-cell layer forming the operculum through which the sperm cells are released.	Sphenophyta, Equisetales, gametophyte	107	Lab09
16-183	16-183t.jpg	16-183v.jpg	59	16-183h.jpg	258	<B><I>Equisetum</i> gametophyte</b> showing placement of archegonia and antheridis	Sphenophyta, Equisetales, gametophyte	108	Lab09
16-182	16-182t.jpg	16-182v.jpg	49	16-182h.jpg	197	<B><I>Equisetum</i> anteridia</b> with nearly mature sperm cells.	Sphenophyta, Equisetales, gametophyte	109	Lab09
16-181	16-181t.jpg	16-181v.jpg	50	16-181h.jpg	196	<B><I>Equisetum</i> archegonia with eggs</b>	Sphenophyta, Equisetales, gametophyte	110	Lab09
16-180	16-180t.jpg	16-180v.jpg	47	16-180h.jpg	189	<B><I>Equisetum</i> embryo</b> during early development.	Sphenophyta, Equisetales, gametophyte	111	Lab09
16-179	16-179t.jpg	16-179v.jpg	84	16-179h.jpg	558	<B><I>Equiseturm</i> maturing embryo</b> with protective leaves surrounding the apex.		111.1	Lab09
16-equise	equisetum-embryo-t.jpg	equisetum-embryo-v.jpg	152	equisetum-embryo-h.jpg	538	<B>Embryogenesis in <I>Equisetum</i></b> from Wardlaw (1954).	Sphenophyta, Equisetales, embryogenesis	111.2	Lab09
16-082	16-082t.jpg	16-082v.jpg	67	16-082h.jpg	411	<B>Zosterophyllophyte in the Devonian</b>. Strobili consist of reniform sporangia on short laterals, and increasing vegetative complexity.	Museum, Devonian, Zosterophyllophyta	119	Lab10
16-081	16-081t.jpg	16-081v.jpg	213	16-081h.jpg	435	<B><I>Psilophyton princeps</i></b>, a Trimerophyte. Plants in this group are believed to be the source of most vascular land plants.	Museum, Devonian, Trimerophyta	120	Lab10
16-084	16-084t.jpg	16-084v.jpg	109	16-084h.jpg	472	<B>Reconstruction of a Devonian scene</b>.  A diorama by the Milwaukee Public Museum.	Museum, Devonian	121	Lab10
16-105	16-105t.jpg	16-105v.jpg	157	16-105h.jpg	2151	<B><I>Botrychium</i> rhizome</b> displaying secondary xylem. Note fibrous matrix with leaf and root traces.	Pteridophyta, Ophioglossales, Botrychium	122	Lab12
16-106	16-106t.jpg	16-106v.jpg	124	16-106h.jpg	1484	<B><I>Botrychium</i> rhizome</b> periderm, a secondary tissue that replaces the epidermis.	Pteridophyta, Ophioglossales, Botrychium	123	Lab12
16-107	16-107t.jpg	16-107v.jpg	143	16-107h.jpg	1764	<B><I>Botrychium</i> rhizome</b> vascular cambium and secondary xylem.	Pteridophyta, Ophioglossales, Botrychium	124	Lab12
16-108	16-108t.jpg	16-108v.jpg	183	16-108h.jpg	2184	<B><I>Botrychium</i> stipe</b> showing the vasculature of the fertile (lower) and sterile (upper) pinnae.	Pteridophyta, Ophioglossales, Botrychium	125	Lab12
16-116	16-116t.jpg	16-116v.jpg	126	16-116h.jpg	1662	<B><I>Botrychium</i> stipe</b> showing departure of fertile vasculature.	Pteridophyta, Ophioglossales, Botrychium	125.5	Lab12
16-109	16-109t.jpg	16-109v.jpg	159	16-109h.jpg	985	<B><I>Botrychium</i> root</b> showing general morphology and central protostele.	Pteridophyta, Ophioglossales, Botrychium	126	Lab12
16-115	16-115t.jpg	16-115v.jpg	158	16-115h.jpg	1629	<B><I>Botrychium</i> shoot apex</b> with multiple layers of foliar units developing from the inside. Only one foliar unit matures each year.	Pteridophyta, Ophioglossales, Botrychium	126.5	Lab12
16-110	16-110t.jpg	16-110v.jpg	170	16-110h.jpg	1901	<B><I>Botrychium</i> root</b> vascular core showing central stele.	Pteridophyta, Ophioglossales, Botrychium	127	Lab12
16-111	16-111t.jpg	16-111v.jpg	110	16-111h.jpg	1579	<B><I>Botrychium</i> sporangium</b> during late sporogenesis, showing its eusporangiate nature. Note tapetum and early post-meiotic spores.	Pteridophyta, Ophioglossales, Botrychium	128	Lab12
16-112	16-112t.jpg	16-112v.jpg	133	16-112h.jpg	1461	<B><I>Botrychium</i> sporagium</b> nearing maturity. Spores dry as they near dispersal.	Pteridophyta, Ophioglossales, Botrychium	129	Lab12
16-113	16-113t.jpg	16-113v.jpg	142	16-113h.jpg	1627	<B><I>Botrychium</i> gametophyte</b> displaying a layer of endophytic fungus. Gametangia develop on the underside.	Pteridophyta, Ophioglossales, Botrychium	130	Lab12
16-114	16-114t.jpg	16-114v.jpg	138	16-114h.jpg	1663	<B><I>Botrychium</i> gametophyte</b> with antheridia  at different developmental stages and archegonia nearby.	Pteridophyta, Ophioglossales, Botrychium	131	Lab12
16-emb	embryo-ophioglossaceae-t.png	embryo-ophioglossaceae-v.png	60	embryo-ophioglossaceae-h.png	150	<B>Embryogenesis in Ophioglossaceae</b> from Wardlaw (1955).	Pteridophyta, Ophioglossales	131.5	Lab12
16-emb	embryo-ophioglossaceae-legend-t.png	embryo-ophioglossaceae-legend-v.png	31	embryo-ophioglossaceae-legend-h.png	73	<B>Embryogenesis in Ophioglossaceae</b> legend corresponding to prior images from Wardlaw (1955).	Pteridophyta, Ophiglossales	131.51	Lab12
16-117	16-117t.jpg	16-117v.jpg	119	16-117h.jpg	890	<B><I>Ophioglossum</i> stipe</b> showing vaculature of the foliar unit.	Pteridophyta, Ophioglossales, Ophioglossum	134	Lab12
16-118	16-118t.jpg	16-118v.jpg	114	16-118h.jpg	1451	<B><I>Ophioglossum</i> fertile spike</b> showing synangiate eusporangia and connective material in cross section.	Pteridophyta, Ophioglossales, Ophioglossum	135	Lab12
16-119	16-119t.jpg	16-119v.jpg	163	16-119h.jpg	1239	<B><I>Ophioglossum</i> fertile spike</b> showing synangiate eusporangia and vasculature in longitudinal section.	Pteridophyta, Ophioglossales, Ophioglossum	136	Lab12
16-120	16-120t.jpg	16-120v.jpg	154	16-120h.jpg	1742	<B><I>Ophioglossum</i> eusporangium</b> showing maturing spores, sporangial walls and tapetum.	Pteridophyta, Ophioglossales, Ophioglossum	137	Lab12
16-121	16-121t.jpg	16-121v.jpg	144	16-121h.jpg	1649	<B><I>Ophioglossum</i> root</b> showing general morphology.	Pteridophyta, Ophioglossales, Ophioglossum	138	Lab12
16-122	16-122t.jpg	16-122v.jpg	200	16-122h.jpg	2005	<B><I>Helminthostachys</i> rhizome</b> showing secondary growth and vascular cambium.	Pteridophyta, Ophioglossales, Helminthostachys	139	Lab12
16-123	16-123t.jpg	16-123v.jpg	204	16-123h.jpg	1999	<B><I>Helminthostachys</i> root</b> showing stelar organization and cortex.	Pteridophyta, Ophioglossales, Helminthostachys	140	Lab12
16-124	16-124t.jpg	16-124v.jpg	154	16-124h.jpg	481	<B><I>Angiopteris</i> plant</b> showing large fronds and pinnae (taken in Tahiti).	Pteridophyta, Marattiales, Angiopteris	141	Lab12
16-125	16-125t.jpg	16-125v.jpg	97	16-125h.jpg	1120	<B><I>Angiopteris</i> rhizome</b> showing the base of its large fronds and clasping stipules.  Multiple aphlebiae are evident on the stipe.	Pteridophyta, Marattiales, Angiopteris	142	Lab12
16-126	16-126t.jpg	16-126v.jpg	82	16-126h.jpg	1265	<B><I>Angiopteris</i> rhizome</b> is vertical, massive and usually quite slow growing.	Pteridophyta, Marattiales, Angiopteris	143	Lab12
16-127	16-127t.jpg	16-127v.jpg	252	16-127h.jpg	3072	<B><I>Angiopteris</i> root</b> vasculature and stelar structure.	Pteridophyta, Marattiales, Angiopteris	144	Lab12
16-128	16-128t.jpg	16-128v.jpg	230	16-128h.jpg	2926	<B><I>Angiopteris</i> root</b> vasculature and stelar structure in cross section.	Pteridophyta, Marattiales, Angiopteris	145	Lab12
16-129	16-129t.jpg	16-129v.jpg	162	16-129h.jpg	2376	<B><I>Angiopteris</i> root</b> vasculature and stele in longitudinal section.	Pteridophyta, Marattiales, Angiopteris	146	Lab12
16-130	16-130t.jpg	16-130v.jpg	139	16-130h.jpg	1148	<B><I>Angiopteris</i> root</b> detail showing weak secondary vasculature and cortical interface in cross section.	Pteridophyta, Marattiales, Angiopteris	147	Lab12
16-131	16-131t.jpg	16-131v.jpg	83	16-131h.jpg	1083	<B><I>Angiopteris</i> sporangia</b> showing the separate nature of their eusporangia.	Pteridophyta, Marattiales, Angiopteris	148	Lab12
16-132	16-132t.jpg	16-132v.jpg	123	16-132h.jpg	1297	<B><I>Angiopteris</i> sporangia</b> showing separation at the base of the eusporangia.  Dehiscence line is longitudinal.	Pteridophyta, Marattiales, Angiopteris	149	Lab12
16-133	16-133t.jpg	16-133v.jpg	77	16-133h.jpg	1089	<B><I>Danea</i> synangium</b> showing abaxial laterally fused eusporangia.	Pteridophyta, Marattiales, Danea	150	Lab12
16-134	16-134t.jpg	16-134v.jpg	119	16-134h.jpg	1282	<B><I>Danea</i> synangium</b> with lateral fusion of eusporangia and abaxial line of dehiscence.	Pteridophyta, Marattiales, Danea	151	Lab12
16-135	16-135t.jpg	16-135v.jpg	142	16-135h.jpg	1468	<B><I>Marattia</i> synangium</b> in longitudinal section with internally opening lines of dehiscence of the eusporangia.	Pteridophyta, Marattiales, Marattia	152	Lab12
16-136	16-136t.jpg	16-136v.jpg	119	16-136h.jpg	1377	<B><I>Marattia</i> synangium</b> in cross section. Sori are fused and separated from the abaxial surface of the frond. The unusual internally dehiscent eusporangia are evident.	Pteridophyta, Marattiales, Marattia	153	Lab12
16-emb	embryo-angiopteris-t.png	embryo-angiopteris-v.png	43	embryo-angiopteris-h.png	120	<B>Embryogenesis in Marattiales</b> - <I>Angiopteris, Danaea, Marattia</i> from Wardlaw (1955)	Pteridophyta, Marattiales	153.001	Lab13
16-163	16-163t.jpg	16-163v.jpg	111	16-163h.jpg	1131	<B><I>Gleichenia</i> sp.</b>	Pteridophyta, Filicales, habit	153.01	Lab13
16-164	16-164t.jpg	16-164v.jpg	81	16-164h.jpg	876	<B><I>Asplenium nidis</i></b> - bird's nest fern	Pteridophyta, Filicales, habit	153.02	Lab13
16-144	16-144t.jpg	16-144v.jpg	148	16-144h.jpg	1814	<B>Circinate vernation</b> of fronds is typical of ferns and may occur in several orders of pinnae.	Pteridophyta, Filicales, habit	153.19	Lab13
16-137	16-137t.jpg	16-137v.jpg	198	16-137h.jpg	1442	<B>Tree fern apex</b> showing developing frond.	Pteridophyta, Filicales, habit	153.2	Lab13
16-138	16-138t.jpg	16-138v.jpg	70	16-138h.jpg	1111	<B>Frond organization</b> is composed of often repeating elements of fractal-like nature.	Pteridophyta, Filicales, habit	153.2	Lab13
16-139	16-139t.jpg	16-139v.jpg	275	16-139h.jpg	2275	<B><I>Dicksonia antarctica</i></b> in Australia	Pteridophyta, Filicales, habit	153.2	Lab13
16-140	16-140t.jpg	16-140v.jpg	260	16-140h.jpg	1447	<B><I>Dicksonia antarctica</i></b> in Australia	Pteridophyta, Filicales, habit	153.2	Lab13
16-141	16-141t.jpg	16-141v.jpg	134	16-141h.jpg	1791	<B>Tree fern shoot apex</b> showing frond maturation	Pteridophyta, Filicales, habit	153.2	Lab13
16-142	16-142t.jpg	16-142v.jpg	257	16-142h.jpg	2876	<B><I>Dicksonia antarctica</i></b> may become as tall as 4-5 meters (to 18 feet).  Fronds are often a meter or longer	Pteridophyta, Filicales, habit, ecology	153.2	Lab13
16-143	16-143t.jpg	16-143v.jpg	331	16-143h.jpg	3248	<B>Tree fern forest</b> in New Zealand temperate rain forest. Tree ferns may dominate the understory.	Pteridophyta, Filicales, habit, ecology	153.29	Lab13
16-165	16-165t.jpg	16-165v.jpg	136	16-165h.jpg	1988	<B><I>Cyathea dealbata</i></b> - Ponga, Silver Tree Fern is a native tree fern of New Zealand.	Pteridophyta, Filicales, habit	153.3	Lab13
16-166	16-166t.jpg	16-166v.jpg	84	16-166h.jpg	366	<B><I>Dicksonia antarctica</i></b> - tree fern, taken at Tidbinbilla Nature Reserve, Australian Capital Territory near Canberra.	Pteridophyta, Filicales, habit	153.3	Lab13
16-147	16-147t.jpg	16-147v.jpg	149	16-147h.jpg	1963	<B><I>Lygodium</i> rhizome</b> showing the stele and fibrous cortical cells.	Pteridophyta, Filicales, stelar anatomy	154	Lab13
16-146	16-146t.jpg	16-146v.jpg	157	16-146h.jpg	1875	<B><I>Lygodium</i> rhizome</b> medullated (or vitalized) protostele. Note the parenchyma cells amid the tracheids.	Pteridophyta, Filicales, stelar anatomy	155	Lab13
16-145	16-145t.jpg	16-145v.jpg	213	16-145h.jpg	3738	<B><I>Gleichenia</i> rhizome</b> with medullated protostele.	Pteridophyta, Filicales, stelar anatomy	156	Lab13
16-155	16-155t.jpg	16-155v.jpg	144	16-155h.jpg	1544	<B><I>Gleichenia</i> rhizome</b> showing divergence of presumed root trace.	Pteridophyta, Filicales, stelar anatomy	157	Lab13
16-151	16-151t.jpg	16-151v.jpg	160	16-151h.jpg	1818	<B><I>Osmunda</i> rhizome</b> with ectophloic dissected siphonostele (eustele).	Pteridophyta, Filicales, stelar anatomy	158	Lab13
16-152	16-152t.jpg	16-152v.jpg	105	16-152h.jpg	1578	<B><I>Osmunda</i> eustele</b> with mesarch maturation.	Pteridophyta, Filicales, vegetative	158.5	Lab13
16-150	16-150t.jpg	16-150v.jpg	133	16-150h.jpg	2028	<B><I>Osmunda</i> rhizome</b> divergence of root and frond traces.	Pteridophyta, Filicales, stelar anatomy	159	Lab13
16-148	16-148t.jpg	16-148v.jpg	162	16-148h.jpg	2122	<B><I>Osmunda</i> rhizome</b> divergence of leaf trace, forming leaf gap.	Pteridophyta, Filicales, stelar anatomy	160	Lab13
16-149	16-149t.jpg	16-149v.jpg	148	16-149h.jpg	2572	<B><I>Osmunda</i> rhizome</b> root trace.	Pteridophyta, Filicales, stelar anatomy	162	Lab13
16-153	16-153t.jpg	16-153v.jpg	135	16-153h.jpg	1678	<B><I>Osmunda</i> with mesarch xylem maturation</b> in ectophloic dissected siphonostele (eustele).	Pteridophyta, Filicales, stelar anatomy	163	Lab13
16-156	16-156t.jpg	16-156v.jpg	153	16-156h.jpg	1342	<B><I>Dicksonia</i> rhizome</b>	Pteridophyta, Filicales, stelar anatomy	164	Lab13
16-157	16-157t.jpg	16-157v.jpg	131	16-157h.jpg	1704	<B><I>Dicksonia</i> rhizome</b>	Pteridophyta, Filicales, stelar anatomy	165	Lab13
16-154	16-154t.jpg	16-154v.jpg	191	16-154h.jpg	2289	<B>Amphiphloic siphonostele</b> showing divergence of root trace.	Pteridophyta, Filicales, stelar anatomy	166	Lab13
16-158	16-158t.jpg	16-158v.jpg	172	16-158h.jpg	2553	<B><I>Adiantum</i> rhizome</b> with diverging frond trace and true leaf gap.	Pteridophyta, Filicales, stelar anatomy	167	Lab13
16-159	16-159t.jpg	16-159v.jpg	230	16-159h.jpg	1910	<B><I>Polypodium</i> rhizome</b> with dissected amphiphloic siphonostele (dictyostele).	Pteridophyta, Filicales, stelar anatomy	168	Lab13
16-160	16-160t.jpg	16-160v.jpg	77	16-160h.jpg	1273	<B><I>Polypodium</i> rhizome</b> with dissected amphiphloic siphonostele (dictyostele).	Pteridophyta, Filicales, stelar anatomy	169	Lab13
16-161	16-161t.jpg	16-161v.jpg	163	16-161h.jpg	1888	<B><I>Pteridium</i> rhizome</b> dissected dictyostele, which contains variegated meristeles, and many different stelar elements.	Pteridophyta, Filicales, stelar anatomy	170	Lab13
16-162	16-162t.jpg	16-162v.jpg	258	16-162h.jpg	3457	<B><I>Matonia</i> rhizome</b> with cyclic amphiphloic siphonostele (solenostele).	Pteridophyta, Filicales, stelar anatomy	171	Lab13
16-167	16-167t.jpg	16-167v.jpg	24	16-167h.jpg	99	<B><I>Lygodium</i> sporangium</b>	Pteridophyta, Filicales, reproductive	200	Lab14
16-317	16-317t.jpg	16-317v.jpg	47	16-317h.jpg	175	<B><I>Lygodium</i> sporangium</b> in cross section.	Pteridophyta, Filicales, reproductive	200.5	Lab14
16-168	16-168t.jpg	16-168v.jpg	35	16-168h.jpg	133	<B><I>Anemia mexicana</i> sporangium</b>	Pteridophyta, Filicales, reproductive	201	Lab14
16-169	16-169t.jpg	16-169v.jpg	39	16-169h.jpg	146	<B><I>Hymenophyllum</i> sorus</b>	Pteridophyta, Filicales, reproductive	202	Lab14
16-170	16-170t.jpg	16-170v.jpg	69	16-170h.jpg	246	<B><I>Trichomanes</i> sorus</b>	Pteridophyta, Filicales, reproductive	203	Lab14
16-171	16-171t.jpg	16-171v.jpg	23	16-171h.jpg	94	<B><I>Trichomanes</i> sporangium</b>	Pteridophyta, Filicales, reproductive	204	Lab14
16-315	16-315t.jpg	16-315v.jpg	31	16-315h.jpg	127	<B><I>Gleichenia</i> sorus</b>	Pteridophyta, Filicales, reproductive	205	Lab14
16-316	16-316t.jpg	16-316v.jpg	28	16-316h.jpg	108	<B><I>Trichomanes</i> sporangia</b>	Pteridophyta, Filicales, reproductive	206	Lab14
16-314	16-314t.jpg	16-314v.jpg	66	16-314h.jpg	264	<B><I>Trichomanes</i> sporangia</b> in cross section.	Pteridophyta, Filicales, reproductive	207	Lab14
16-248	16-248t.jpg	16-248v.jpg	39	16-248h.jpg	159	<B><I>Osmunda</i> sporangia</b> in darkfield microscopy	Pteridophyta, Filicales, reproductive	208	Lab14
16-247	16-247t.jpg	16-247v.jpg	78	16-247h.jpg	296	<B><I>Osmunda</i> sporangia & sorus</b> in cross section	Pteridophyta, Filicales, reproductive	209	Lab14
16-245	16-245t.jpg	16-245v.jpg	36	16-245h.jpg	151	<B><I>Cyathea</i> sporangia</b> in darkfield microscopy	Pteridophyta, Filicales, reproductive	210	Lab14
16-246	16-246t.jpg	16-246v.jpg	48	16-246h.jpg	177	<B><I>Cyathea</i> sporangia</b> in cross section	Pteridophyta, Filicales, reproductive	211	Lab14
16-249	16-249t.jpg	16-249v.jpg	58	16-249h.jpg	245	<B><I>Onoclea</i> sori</b> are located on fertile pinnae	Pteridophyta, Filicales, reproductive	212	Lab14
16-311	16-311t.jpg	16-311v.jpg	44	16-311h.jpg	178	<B><I>Cyrtomium</i> sporangia</b> in darkfield microscopy	Pteridophyta, Filicales, reproductive	213	Lab14
16-310	16-310t.jpg	16-310v.jpg	85	16-310h.jpg	322	<B><I>Cyrtomium falcatum</i> sorus</b> with peltate indusium	Pteridophyta, Filicales, reproductive	214	Lab14
16-307	16-307t.jpg	16-307v.jpg	48	16-307h.jpg	202	<B><I>Pteridium</i> sporangia</b> in cross section showing developmental stages	Pteridophyta, Filicales, reproductive	215	Lab14
16-309	16-309t.jpg	16-309v.jpg	78	16-309h.jpg	287	<B><I>Polypodium</i> sorus</b> showing sporangia at many developmental stages	Pteridophyta, Filicales, reproductive	216	Lab14
16-308	16-308t.jpg	16-308v.jpg	21	16-308h.jpg	106	<B><I>Polypodium</i> sporangium</b>	Pteridophyta, Filicales, reproductive	217	Lab14
16-306	16-306t.jpg	16-306v.jpg	135	16-306h.jpg	135	<B>Fern prothallus</b> or gametophyte. Gametangia are present on the archegonial pad, beneath the apical notch and above rhizoids.	Pteridophyta, Filicales, sexual reproductive	230	Lab14
16-305	16-305t.jpg	16-305v.jpg	272	16-305h.jpg	272	<B>Fern archgonia</b> on archegonial pad.	Pteridophyta, Filicales, sexual reproductive	231	Lab14
16-303	16-303t.jpg	16-303v.jpg	226	16-303h.jpg	226	<B>Fern antheridia</b> beneath the apical notch.	Pteridophyta, Filicales, sexual reproductive	232	Lab14
16-304	16-304t.jpg	16-304v.jpg	211	16-304h.jpg	211	<B>Fern archegonia</b> in cross section.	Pteridophyta, Filicales, sexual reproductive	233	Lab14
16-302	16-302t.jpg	16-302v.jpg	120	16-302h.jpg	120	<B>Fern antheridium</b> with nearly mature sperm cells.	Pteridophyta, Filicales, reproductive	234	Lab14
16-178	16-178t.jpg	16-178v.jpg	187	16-178h.jpg	187	<B>Fern embryo</b> developing from an archegonium near the center of the gametophyte.	Pteridophyta, Filicales, reproductive	235	Lab14
16-emb	embryo-fern-zygotes-t.png	embryo-fern-zygotes-v.png	46	embryo-fern-zygotes-h.png	104	<B>Overview of fern embryogenesis</b> from Wardlaw (1955).	Pteridophyta, Filicales	235.1	Lab14
16-emb	embryo-osmunda-matonia-t.png	embryo-osmunda-matonia-v.png	96	embryo-osmunda-matonia-h.png	155	<B>Embryogenesis in <I>Osmunda</i> and <I>Matonia</i></b> from Wardlaw (1955).	Pteridophyta, Filicales, Osmunda, Matonia	235.2	Lab14
16-emb	embryo-gymnogramme-t.png	embryo-gymnogramme-v.png	68	embryo-gymnogramme-h.png	199	<B>Embryogenesis in <I>Gymnogramme</i></b> a filicalean fern, from Wardlaw (1955).	Pteridophyta, Filicales, Gymnogamme	235.3	Lab14
16-emb	embryo-pteris-t.png	embryo-pteris-v.png	78	embryo-pteris-h.png	123	<B>Embryogenesis in <I>Pteris</i></b> from Wardlaw (1955).	Pteridophyta, Filicales, Pteris	235.4	Lab14
16-177	16-177t.jpg	16-177v.jpg	81	16-177h.jpg	377	<B><I>Marsilea</i> rhizome</b> with highly sclerified cortical walls.	Pteridophyta, Marsileales, vegetative	236	Lab15
16-176	16-176t.jpg	16-176v.jpg	39	16-176h.jpg	619	<B><I>Marsilea</i> sporocarp</b> longitudinal section.	Pteridophyta, Marsileales, heterosporous reproduction	237	Lab15
16-175	16-175t.jpg	16-175v.jpg	65	16-175h.jpg	571	<B><I>Marsilea</i> sporocarp</b> in longitudinal section.	Pteridophyta, Marsileales, heterosporous reproduction	238	Lab15
16-174	16-174t.jpg	16-174v.jpg	65	16-174h.jpg	972	<B><I>Marsilea</i> sporocarp</b> showing microsporangia and megasporangia in near medium longitudinal section. Indusia evident.	Pteridophyta, Marsileales, heterosporous reproduction	239	Lab15
16-173	16-173t.jpg	16-173v.jpg	60	16-173h.jpg	883	<B><I>Marsilea</i> sporocarp</b> showing microsporangia and megasporangia.	Pteridophyta, Marsileales, heterosporous reproduction	240	Lab15
16-172	16-172t.jpg	16-172v.jpg	59	16-172h.jpg	1246	<B><I>Marsilea</i> sporocarp contents</b> containing microspores and megaspores.	Pteridophyta, Marsileales, heterosporous reproduction	241	Lab15
16-mars	marsilea-fert-bf-t.jpg	marsilea-fert-bf-v.jpg	30	marsilea-fert-bf-h.jpg	157	<B><I>Marsilea</i> fertilized megasporangium</b>. The grayish material in the surrounding gelatin consists of sperm and sperm trails. Brightfield illumination.	Pteridophyta, Marsileales, heterosporous reproduction	241.1	Lab15
16-mars	marsilea-fert2-t.jpg	marsilea-fert2-v.jpg	46	marsilea-fert2-h.jpg	236	<B><I>Marsilea</i> fertilized megasporangium</b>. The light material in surrounding gelatin are sperm and sperm trails. Darkfield illumination.	Pteridophyta, Marsileales, heterosporous reproduction	241.2	Lab15
16-mars	marsilea-spermlake2-t.jpg	marsilea-spermlake2-v.jpg	33	marsilea-spermlake2-h.jpg	192	<B><I>Marsilea</i> fertilized megasporangium</b>. The light material in surrounding gelatin are sperm and sperm trails. Darkfield illumination.	Pteridophyta, Marsileales, heterosporous reproduction	241.3	Lab15
16-mars	marsilea-sperm-40-125a-t.jpg	marsilea-sperm-40-125a-v.jpg	15	marsilea-sperm-40-125a-h.jpg	141	<B><I>Marsilea</i> sperm cells</b> in the gelatin matrix surrounding the megagametophyte. Differential interference contrast microscopy.	Pteridophyta, Marsileales, heterosporous reproduction	241.4	Lab15
16-mars	marsilea-archneck-t.jpg	marsilea-archneck-v.jpg	31	marsilea-archneck-h.jpg	175	<B><I>Marsilea</i> fertilized megasporangium</b>with sperm and sperm trails in the sperm lake.  Interference contrast microscopy.	Pteridophyta, Marsileales, heterosporous reproduction	241.5	Lab15
16-mars	marsilea-archneck-vert-t.jpg	marsilea-archneck-vert-v.jpg	30	marsilea-archneck-vert-h.jpg	171	<B><I>Marsilea</i> fertilized megasporangium</b> with archegonial neck cells showing and disintegrated axial row. Many sperm cells are present in the matrix.	Pteridophyta, Marsileales, heterosporous reproduction	241.6	Lab15
16-250	16-250-t.jpg	16-250-v.jpg	133	16-250-h.jpg	479	<B><I>Azolla</I> sporocarps</B> megasporocarps and microsporocarps, completing the separation of sexes in the heterosporous ferns.	Pteridophyta, Marsileales, heterosporous reproduction	242	Lab15
16-emb	embryo-marsileales-t.png	embryo-marsileales-v.png	89	embryo-marsileales-h.png	242.1	<B>Embryogenesis in heterosporous ferns</b> from Wardlaw (1955).	Pteridophyta, Marsileales, Salviniales	141.9	Lab12
16-266	16-266t.jpg	16-266v.jpg	62	16-266h.jpg	249	<B><I>Cycas revoluta</i></b> female cone, consisting of loose sporophylls.	Cycadophyta, habit, strobilus	250	Lab18
16-265	16-265t.jpg	16-265v.jpg	139	16-265h.jpg	324	<B><I>Cycas revoluta</i></b> male cone.	Cycadophyta, habit, strobilus	251	Lab18
16-264	16-264t.jpg	16-264v.jpg	123	16-264h.jpg	561	<B><I>Dioon edule</i></b> plant habit in Linares Canyon, Nuevo Leon, Mexico.	Cycadophyta, habit, strobilus	252	Lab18
16-263	16-263t.jpg	16-263v.jpg	95	16-263h.jpg	389	<B><I>Dioon edule</i></b> male cone and cycad leaf structure.	Cycadophyta, habit, strobilus	253	Lab18
16-262	16-262t.jpg	16-262v.jpg	118	16-262h.jpg	280	<B><I>Dioon edule</i></b> male cone.	Cycadophyta, habit, strobilus	254	Lab18
16-261	16-261t.jpg	16-261v.jpg	65	16-261h.jpg	298	<B><I>Dioon edule</i></b> microsporophylls with numerous microsporangia.	Cycadophyta, habit, strobilus	255	Lab18
16-260	16-260t.jpg	16-260v.jpg	107	16-260h.jpg	467	<B><I>Encephalartos altensteini</i></b> plant habit in Huntington Gardens.	Cycadophyta, habit, strobilus	256	Lab18
16-258	16-258t.jpg	16-258v.jpg	176	16-258h.jpg	380	<B><I>Encephalartos altensteini</i></b> male cone at Sydney Botanical Garden.	Cycadophyta, habit, strobilus	257	Lab18
16-259	16-259t.jpg	16-259v.jpg	146	16-259h.jpg	314	<B><I>Encephalartos altensteini</i></b> male cone at Melbourne Royal Botanical Garden.	Cycadophyta, habit, strobilus	258	Lab18
16-257	16-257t.jpg	16-257v.jpg	76	16-257h.jpg	352	<B><I>Encephalartos villosis</i></b> male cone at Adelaide Botanical Garden, Australia.	Cycadophyta, habit, strobilus	259	Lab18
16-255	16-255t.jpg	16-255v.jpg	119	16-255h.jpg	529	<B><I>Microcycas calocoma</i></b>, genus native to Cuba, seen at Pinar del R?o, Cuba.	Cycadophyta, habit, strobilus	260	Lab18
16-256	16-256t.jpg	16-256v.jpg	113	16-256h.jpg	492	<B><I>Microcycas calocoma</i></b>, showing an apparently female cone, at Pinar del R?o, Cuba.	Cycadophyta, habit, strobilus	261	Lab18
16-251	16-251t.jpg	16-251v.jpg	77	16-251h.jpg	320	<B><I>Macrozamia</i> sp.</b> with female cone at Sydney Botanical Garden.	Cycadophyta, habit, strobilus	262	Lab18
16-254	16-254t.jpg	16-254v.jpg	119	16-254h.jpg	298	<B><I>Zamia skinneri</i></b> Turrialba, Costa Rica.	Cycadophyta, habit, strobilus	263	Lab18
16-268	16-268t.jpg	16-268v.jpg	104	16-268h.jpg	523	<B><I>Cycas</i> stem</b> cross section illustrating manoxylic development and girdling leaf traces.	Cycadophyta, vegetative	264	Lab18
16-269	16-269t.jpg	16-269v.jpg	61	16-269h.jpg	341	<B><I>Cycas</i> petiole</b> cross section.	Cycadophyta, vegetative	265	Lab18
16-270	16-270t.jpg	16-270v.jpg	53	16-270h.jpg	230	<B><I>Cycas</i> petiole vascular bundle</b> cross section.	Cycadophyta, vegetative	266	Lab18
16-267	16-267t.jpg	16-267v.jpg	60	16-267h.jpg	255	<B><I>Cycas</i> tracheids</b> in macerated wood.	Cycadophyta, vegetative	266.1	Lab18
16-253	16-253-t.jpg	16-253-v.jpg	71	16-253-h.jpg	285	<B><I>Zamia</i> male cone</b> in cross section, showing manoxylic wood and placement of sporophylls.	Cycadophyta, Cycadales, reproductive, microsporangiate strobilus	266.5	Lab19
16-252	16-252-t.jpg	16-252-v.jpg	105	16-252-h.jpg	405	<B><I>Zamia</i> male cone</b> in cross section, showing placement of microsporangia on sporophyll.	Cycadophyta, Cycadales, reproductive, microsporangiate strobilus	266.51	Lab19
16-283	16-283-t.jpg	16-283-v.jpg	84	16-283-h.jpg	305	<B><I>Zamia</i> microsporangia</b> are frequently paired or grouped, as showin in this longitudinal section.	Cycadophyta, Cycadales, reproductive, microsporogenesis	266.53	Lab19
16-284	16-284-t.jpg	16-284-v.jpg	81	16-284-h.jpg	332	<B><I>Zamia</i> young ovule</b>, showing integument surrounding the megasporangium (=nucellus).	Cycadophyta, Cycadales, reproductive, megasporogenesis	267	Lab19
16-255	16-255-t.jpg	16-255-v.jpg	87	16-255-h.jpg	347	<B><I>Zamia</i> young ovule</b>, showing the broad integument surrounding the nucellus (=megasporangium).	Cycadophyta, Cycadales, reproductive, megasporogenesis	267.1	Lab19
16-287	16-287-t.jpg	16-287-v.jpg	118	16-287-h.jpg	478	<B><I>Zamia</i> young ovule</b>, showing micropyle formed by the integument. The female gametophyte will form at the center of the megasporangium.	Cycadophyta, Cycadales, reproductive, megasporogenesis	267.12	Lab19
16-288	16-288-t.jpg	16-288-v.jpg	49	16-288-h.jpg	202	<B><I>Zamia</i> ovule</b>, showing free nuclear division, an initial stage of megagametogenesis.	Cycadophyta, Cycadales, reproductive, megagametogenesis	267.13	Lab19
16-286	16-286-t.jpg	16-286-v.jpg	82	16-286-h.jpg	296	<B><I>Zamia</i> pollen tubes</b> growing into the surface of the nucellus.	Cycadophyta, Cycadales, reproductive, megasporogenesis	267.2	Lab19
16-289	16-289-t.jpg	16-289-v.jpg	49	16-289-h.jpg	217	<B><I>Zamia</i> archegonium</b>, showing large egg cell and smaller ventral canal cell.  Archegonial jacket cells develop from surrounding nucellus.	Cycadophyta, Cycadales, reproductive, megagametophyte	267.21	Lab19
16-290	16-290-t.jpg	16-290-v.jpg	63	16-290-h.jpg	263	<B><I>Zamia</i> archegonium</b>, showing single cover cell just over the ventral canal cell.  The large egg cell is just below.	Cycadophyta, Cycadales, reproductive, megagametophyte	267.22	Lab19
16-291	16-291-t.jpg	16-291-v.jpg	53	16-291-h.jpg	237	<B><I>Stangeria paradoxa</i> pollen tubes</b>, showing male gamete development at three stages, from body cell to sperm cell formation. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.3	Lab19
16-292	16-292-t.jpg	16-292-v.jpg	68	16-292-h.jpg	258	<B><I>Zamia</i> microgametophyte</b>, showing sperm cells forming within the region of the archegonial chamber. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.31	Lab19
16-293	16-293-t.jpg	16-293-v.jpg	164	16-293-h.jpg	317	<B><I>Zamia</i> sperm cell</b> with a large nucleus, conspicuous nucleolus and a prominent blepharoplast, which is the organelle that organizes microtubule distribution in the cell, similar to a centriole. (Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.32	Lab19
16-295	16-295-t.jpg	16-295-v.jpg	65	16-295-h.jpg	261	<B><I>Zamia</i> microgametophyte</b> elongating into the archegonial chamber. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.33	Lab19
16-294	16-294-t.jpg	16-294-v.jpg	54	16-294-h.jpg	217	<B><I>Zamia</i> microgametophytes</b>, showing sperm cells maturing and near release, within the archegonial chamber. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.34	Lab19
16-296	16-296-t.jpg	16-296-v.jpg	61	16-296-h.jpg	246	<B><I>Zamia</i> mature sperm cell</b>, showing numerous flagellae located in the helical multi-lamellar structure (MLS) at sperm summit. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.4	Lab19
16-zam	zamia-sperm-t.jpg	zamia-sperm-v.jpg	141	zamia-sperm-h.jpg	263	<B><I>Zamia</i> sperm cell</b>, activated within the microgametophyte. Original microscope slide by Chamberlain.	Cycadophyta, reproductive, male gamete	267.42	Lab19
16-297	16-297-t.jpg	16-297-v.jpg	43	16-297-h.jpg	198	<B><I>Zamia</i> mature sperm cell</b>, showing numerous flagellae located in the helical multi-lamellar structure (MLS) at the summit of the cell. (Microscope slide from Chamberlain collection).	Cycadophyta, Cycadales, reproductive, microgametophyte	267.45	Lab19
16-298	16-298-t.jpg	16-298-v.jpg	65	16-298-h.jpg	308	<B><I>Zamia</i> embryogenesis</b> showing the apex of the embryo, deep within the megagametophyte.	Cycadophyta, Cycadales, reproductive, embryogenesis	267.61	Lab19
16-299	16-299-t.jpg	16-299-v.jpg	63	16-299-h.jpg	261	<B><I>Zamia</i> embryogenesis</b> showing the apex of the embryo, deep within the megagametophyte. Cotyledons have not yet formed.	Cycadophyta, Cycadales, reproductive, embryogenesis	267.62	Lab19
16-301	16-301-t.jpg	16-301-v.jpg	70	16-301-h.jpg	301	<B><I>Zamia</i> embryogenesis</b> showing maturing embryo.	Cycadophyta, Cycadales, reproductive, embryogenesis	267.63	Lab19
16-300	16-300-t.jpg	16-300-v.jpg	81	16-300-h.jpg	344	<B><I>Zamia</i> embryogenesis</b> showing maturing embryo.	Cycadophyta, Cycadales, reproductive, embryogenesis	267.64	Lab19
16-emb	embryo-cycad-t.png	embryo-cycad-v.png	47	embryo-cycad-h.png	137	<B>Embryogenesis in Cycads</b>	Cycadophyta, Cycadales	267.8	Lab19
16-emb	embryo-cycad-legend-t.png	embryo-cycad-legend-v.png	15	embryo-cycad-legend-h.png	33	<B>Embryogenesis in Cycads</b> legend corresponding to prior images from Wardlaw (1955).	Cycadophyta, Cycadales	267.81	Lab19
16-273	16-273t.jpg	16-273v.jpg	114	16-273h.jpg	477	<B><I>Ginkgo biloba</i> short shoot</b>, showing manoxylic wood.	Ginkgophyta, vegetative	268	Lab18
16-272	16-272t.jpg	16-272v.jpg	96	16-272h.jpg	390	<B><I>Ginkgo biloba</i> long shoot</b>, showing pycnoxylic wood.	Ginkgophyta, vegetative	268.5	Lab18
16-282	16-282t.jpg	16-282v.jpg	88	16-282h.jpg	404	<B><I>Ginkgo biloga</i> shoot apex</b>	Ginkgophyta, reproductive	269	Lab19
16-274	16-274t.jpg	16-274v.jpg	152	16-274h.jpg	332	<B><I>Ginkgo</i> male sporangiophyll</b>	Ginkgophyta, reproductive	270	Lab19
16-275	16-275t.jpg	16-275v.jpg	43	16-275h.jpg	194	<B><I>Ginkgo</i> pollen development</b>	Ginkgophyta, reproductive	271	Lab19
16-276	16-276t.jpg	16-276v.jpg	63	16-276h.jpg	346	<B><I>Ginkgo</i> ovule</b> with thick integuments located on female sporangiophyll.	Ginkgophyta, reproductive	272	Lab19
16-277	16-277t.jpg	16-277v.jpg	200	16-277h.jpg	429	<B><I>Ginkgo</i> ovule</b> showing thick integuments and nucellus	Ginkgophyta, reproductive	273	Lab19
16-278	16-278t.jpg	16-278v.jpg	95	16-278h.jpg	222	<B><I>Ginkgo</i> ovule</b> showing free nuclear division during megagametogenesis.	Ginkgophyta, reproductive	274	Lab19
16-279	16-279t.jpg	16-279v.jpg	75	16-279h.jpg	364	<B><I>Ginkgo</i> megagametophyte</b> showing cell layering and storage nutrition.	Ginkgophyta, reproductive	275.1	Lab19
16-280	16-280t.jpg	16-280v.jpg	72	16-280h.jpg	359	<B><I>Ginkgo</i> megagametophyte</b> with archegonium.	Ginkgophyta, reproductive	275.2	Lab19
16-281	16-281t.jpg	16-281v.jpg	176	16-281h.jpg	396	<B><I>Ginkgo biloga</i> embryo</b> shoot apex.	Ginkgophyta, reproductive	275.3	Lab19
16-emb	embryo-ginkgo-t.png	embryo-ginkgo-v.png	93	embryo-ginkgo-h.png	159	<B>Embryogenesis in <I>Ginkgo</i></b> from Wardlaw (1955).	Ginkgophyta, Ginkgo	275.4	Lab19
16-emb	embryo-ginkgo-legend-t.png	embryo-ginkgo-legend-v.png	9	embryo-ginkgo-legend-h.png	20	<B>Embryogenesis in <I>Ginkgo</i></b> legend corresponding to prior images from Wardlaw (1955).	Ginkgophyta, Ginkgo	275.41	Lab19
16-335	16-335t.jpg	16-335v.jpg	59	16-335h.jpg	451				
16-336	16-336t.jpg	16-336v.jpg	58	16-336h.jpg	427				
16-337	16-337t.jpg	16-337v.jpg	59	16-337h.jpg	410				
16-338	16-338t.jpg	16-338v.jpg	133	16-338h.jpg	446				
16-339	16-339t.jpg	16-339v.jpg	81	16-339h.jpg	534				
16-340	16-340t.jpg	16-340v.jpg	40	16-340h.jpg	148				
16-341	16-341t.jpg	16-341v.jpg	96	16-341h.jpg	405				
16-342	16-342t.jpg	16-342v.jpg	96	16-342h.jpg	669				
16-343	16-343t.jpg	16-343v.jpg	92	16-343h.jpg	422				
16-344	16-344t.jpg	16-344v.jpg	154	16-344h.jpg	540				
16-345	16-345t.jpg	16-345v.jpg	129	16-345h.jpg	536				
16-346	16-346t.jpg	16-346v.jpg	347	16-346h.jpg	513				
16-347	16-347t.jpg	16-347v.jpg	25	16-347h.jpg	647				
16-348	16-348t.jpg	16-348v.jpg	61	16-348h.jpg	661				
16-349	16-349t.jpg	16-349v.jpg	115	16-349h.jpg	505				
16-350	16-350t.jpg	16-350v.jpg	80	16-350h.jpg	246				
16-351	16-351t.jpg	16-351v.jpg	158	16-351h.jpg	997				
16-352	16-352t.jpg	16-352v.jpg	64	16-352h.jpg	281				
16-353	16-353t.jpg	16-353v.jpg	67	16-353h.jpg	428				
16-354	16-354t.jpg	16-354v.jpg	148	16-354h.jpg	667				
16-355	16-355t.jpg	16-355v.jpg	100	16-355h.jpg	644				
16-356	16-356t.jpg	16-356v.jpg	64	16-356h.jpg	268				
16-357	16-357t.jpg	16-357v.jpg	57	16-357h.jpg	458				
16-358	16-358t.jpg	16-358v.jpg	198	16-358h.jpg	374				
16-359	16-359t.jpg	16-359v.jpg	183	16-359h.jpg	800				
16-360	16-360t.jpg	16-360v.jpg	116	16-360h.jpg	874				
16-361	16-361t.jpg	16-361v.jpg	99	16-361h.jpg	531				
16-362	16-362t.jpg	16-362v.jpg	125	16-362h.jpg	1159				
16-363	16-363t.jpg	16-363v.jpg	178	16-363h.jpg	757				
16-364	16-364t.jpg	16-364v.jpg	211	16-364h.jpg	966				
16-365	16-365t.jpg	16-365v.jpg	238	16-365h.jpg	817				
16-366	16-366t.jpg	16-366v.jpg	122	16-366h.jpg	1069				
16-367	16-367t.jpg	16-367v.jpg	97	16-367h.jpg	1064				
16-368	16-368t.jpg	16-368v.jpg	200	16-368h.jpg	1056				
16-369	16-369t.jpg	16-369v.jpg	280	16-369h.jpg	897				
16-370	16-370t.jpg	16-370v.jpg	227	16-370h.jpg	780				
16-371	16-371t.jpg	16-371v.jpg	118	16-371h.jpg	865				
16-372	16-372t.jpg	16-372v.jpg	118	16-372h.jpg	906				
16-373	16-373t.jpg	16-373v.jpg	113	16-373h.jpg	799				
16-374	16-374t.jpg	16-374v.jpg	134	16-374h.jpg	647				
16-375	16-375t.jpg	16-375v.jpg	286	16-375h.jpg	1360				
16-376	16-376t.jpg	16-376v.jpg	156	16-376h.jpg	1359				
16-377	16-377t.jpg	16-377v.jpg	261	16-377h.jpg	1485				
16-378	16-378t.jpg	16-378v.jpg	191	16-378h.jpg	946				
16-379	16-379t.jpg	16-379v.jpg	113	16-379h.jpg	420				
16-380	16-380t.jpg	16-380v.jpg	208	16-380h.jpg	763				
16-381	16-381t.jpg	16-381v.jpg	271	16-381h.jpg	1117				
16-382	16-382t.jpg	16-382v.jpg	258	16-382h.jpg	1285				
16-383	16-383t.jpg	16-383v.jpg	314	16-383h.jpg	1272				
16-384	16-384t.jpg	16-384v.jpg	180	16-384h.jpg	914				
16-emb	embryo-pinus-t.png	embryo-pinus-v.png	38	embryo-pinus-h.png	91	<B>Embryogenesis in <I>Pinus</i></b> from Wardlaw (1955).	Coniferophyta, Pinophyta, Pinales, Pinaceae		
16-evo	evolution-cupule-t.png	evolution-cupule-v.png	61	evolution-cupule-h.png	164	<B>Evolution of the second integument</b> from Stewart and Rothwell (1992)	Evolution, Lecture, Ovule		
16-evo	evolution-lepidodendrales-t.png	evolution-lepidodendrales-v.png	20	evolution-lepidodendrales-h.png	44	<B>Evolution of ovule postion</b> on sporophyll from Stewart and Rothwell (1992).	Evolution, Lecture, Ovule		
16-evo	evolution-microphylls-t.png	evolution-microphylls-v.png	24	evolution-microphylls-h.png	64	<B>Evolution of Microsporophylls</b> - in Lycophyta (left) and Sphenophyta (right) from Stewart & Rothwell (1993).	Evolution, Lecture, Paleobotany		
16-evo	evolution-microsporophyll-t.png	evolution-microsporophyll-v.png	18	evolution-microsporophyll-h.png	41	<B>Origin of Lycophyta sporophyll</b> by phyletic slide, from Stewart & Rothwell (1993).	Evolution, Lecture, Sporophyll		
16-evo	evolution-of-integument-t.png	evolution-of-integument-v.png	44	evolution-of-integument-h.png	129	<B>Origin of integument</b> by the telome theory from Stewart & Rothwell (1993)	Evolution, Lecture, Ovule		
16-evo	evolution-ovule-pollination-droplet-t.png	evolution-ovule-pollination-droplet-v.png	73	evolution-ovule-pollination-droplet-h.png	162	<B>Pollination droplets</b> - earliest evidence of an old mechanism from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-evo	evolution-pre-cupule-t.png	evolution-pre-cupule-v.png	64	evolution-pre-cupule-h.png	159	<B>Origin of integument</b> by the telome theory from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-evo	evolution-protolepidodendrales-t.png	evolution-protolepidodendrales-v.png	17	evolution-protolepidodendrales-h.png	37	<B>Origin of Protolepidodenralean sporangial position</b> according to telome theory from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-evo	evolution-sporangial-position-summary-t.png	evolution-sporangial-position-summary-v.png	51	evolution-sporangial-position-summary-h.png	126	<B>Summary of origin of sporangial position</b> from Stewart & Rothwell (1993)	Evolution, Lecture, Ovule		
16-lyg	lyginopteris-t.png	lyginopteris-v.png	58	lyginopteris-h.png	133	<B><I>Lyginopteris oldhamia</i>,/B> leaves and reproductive organs from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-lyg	lyginopteris-summary-t.png	lyginopteris-summary-v.png	88	lyginopteris-summary-h.png	227	<B>Overview of Lyginopterid</b> from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-ovu	ovule-eurystoma-t.png	ovule-eurystoma-v.png	31	ovule-eurystoma-h.png	45	<B><I>Eurystoma</i> ovule</b> telome truss from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-ovu	ovule-evolution-t.png	ovule-evolution-v.png	47	ovule-evolution-h.png	123	<B>Overview of ovule evolution</b> from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-ovu	ovule-lagenostoma-t.png	ovule-lagenostoma-v.png	41	ovule-lagenostoma-h.png	93	<B><I>Laginostoma ovoides</i> cupulate ovule</b>  from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-ovu	ovule-lagenostome-t.png	ovule-lagenostome-v.png	22	ovule-lagenostome-h.png	48	<B>Organization of the lagenostome</b> in early ovules from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		
16-ovu	ovule-pinus-t.png	ovule-pinus-v.png	23	ovule-pinus-h.png	50	<B><I>Pinus</i> ovule schematic</b> from Stewart & Rothwell (1993).	Evolution, Lecture, Ovule		Lab21
16-pha	phaseolus-t.png	phaseolus-v.png	30	phaseolus-h.png	72	<B>Hypogeal maturation</b> in <I>Phaseolus</i> from Troll (1938)	Evolution, Lecture, Seed germination		
16-ric	ricinus-t.png	ricinus-v.png	34	ricinus-h.png	84	<B>Epigeal maturation</b> in <I>Ricinus</i> from Troll (1938).	Evolution, Lecture, Seed Germination		
16-telome	telome-theory-1-t.png	telome-theory-1-v.png	37	telome-theory-1-h.png	105	<B>Telome concepts</b>: syngenesis, reduction, fusion, recurvation. Illustration from Stewart & Rothwell (1993).	Evolution, Lecture, Telome theory		
16-telome	telome-theory-megaphyll-t.png	telome-theory-megaphyll-v.png	30	telome-theory-megaphyll-h.png	77	<B>Origin of the megaphyll</b> using the telome theory to obtain modern leaf organization from Stewart & Rothwell (1993).	Evolution, Lecture, Telome theory		
16-typ	type-ideal-plants-t.png	type-ideal-plants-v.png	35	type-ideal-plants-h.png	71	<B>Comparative growth patterns</b> from early ontogeny help to determine the overall organization of plants (illustration from Troll, 1938).	Evolution, Lecture, General Homology		Lab01
16-typ	type-seed-plant-t.png	type-seed-plant-v.png	31	type-seed-plant-h.png	68	<B>Another Idealized Plant</b> with a modernesque look.	Evolution, Lecture, General Homology		Lab01
16-urp	urpflanze-t.png	urpflanze-v.png	45	urpflanze-h.png	116	<B>Urpflanze</b> is an ultimate plant with all potential organs at all developmental stages, regarded as a basis for plant comparison and change (illustration from Troll, 1938).	Evolution, Lecture, General Homology		Lab01
16-213	16-213-t.jpg	16-213-v.jpg	88	16-213-h.jpg	344	<B><I>Sequoiadendron giganteum</i></b>, also known as Giant Sequoia or the Bigtee. The base of the tree may be in excess of 4 meters.	Coniferophyta, Coniferales, Cupressaceae, habit		Lab20
16-215	16-215-t.jpg	16-215-v.jpg	88	16-215-h.jpg	297	<B><I>Sequoiadendron giganteum</i></b> in a grove of giant sequoia trees.	Coniferophyta, Coniferales, Cupressaceae, habit		Lab20
16-216	16-216-t.jpg	16-216-v.jpg	174	16-216-h.jpg	307	<B><I>Sequoiadendron giganteum</i></b> view of the first branches, which may be as high as 20 or more meters above the ground.	Coniferophyta, Coniferales, Cupressaceae, habit		Lab20
16-217	16-217-t.jpg	16-217-v.jpg	40	16-217-h.jpg	159	<B><I>Pinus</i> pollen</b>, showing prothallial, generative and tube cells in the microgametophyte.	Coniferophyta, Coniferales, Pinaceae, reproductive, microgametophyte		Lab21
16-218	16-218-t.jpg	16-218-v.jpg	135	16-218-h.jpg	244	<B><I>Pinus</i> male cone</b>, or microsporangiate strobilis, showing the vasculature in cleared material.	Coniferophyta, Coniferales, Pinaceae, reproductive, strobilus		Lab21
16-219	16-219-t.jpg	16-219-v.jpg	72	16-219-h.jpg	250	<B><I>Pinus</i> male cone</b>, or microsporangiate strobilis, in longitudinal section.	Coniferophyta, Coniferales, Pinaceae, reproductive, strobilus		Lab21
16-220	16-220-t.jpg	16-220-v.jpg	54	16-220-h.jpg	196	<B><I>Pinus</i> transfusion zone</b>, consisting of tracheids located in the leaf's central vascular region.	Coniferophyta, Coniferales, Pinaceae, vegetative		Lab20
16-221	16-221-t.jpg	16-221-v.jpg	59	16-221-h.jpg	261	<B><I>Pinus</i> tracheids</b>, as viewed in macerated secondary xylem, or wood.	Coniferophyta, Coniferales, Pinaceae, vegetative		Lab20
16-222	16-222-t.jpg	16-222-v.jpg	48	16-222-h.jpg	172	<B><I>Podocarpus</i> leaf</b>, an example of a strap-shaped leaf, viewed in cross section. Note mesophyll differentiation.	Coniferophyta, Coniferales, Podocarpaceae, vegetative		Lab20
16-223	16-223-t.jpg	16-223-v.jpg	93	16-223-h.jpg	329	<B><I>Pinus</i> leaf</b>, with two traces in a common vascular region. There is modest secondary growth in the needle, allowing multiple seasons of activity. Note mesophyll differentiation.	Coniferophyta, Coniferales, Pinaceae, vegetative		Lab20
16-225	16-225-t.jpg	16-225-v.jpg	120	16-225-h.jpg	406	<B><I>Phyllocladus</i> phylloclad</b> --  this organ displays the characteristic vasculature of a branch.	Coniferophyta, Coniferales, Pinaceae, vegetative		Lab20
16-226	16-226-t.jpg	16-226-v.jpg	84	16-226-h.jpg	298	<B><I>Cupressus arizonica</i> male and female cones</b>. This species has numerous small microsporangiate strobili and woody, round megasporangiate cones.	Coniferophyta, Coniferales, Cupressaceae, reproductive		Lab21
16-227	16-227-t.jpg	16-227-v.jpg	26	16-227-h.jpg	109	<B><I>Larix europaea?</i> male and female cones</b>. These larch cones mature within a single season.	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-228	16-228-t.jpg	16-228-v.jpg	77	16-228-h.jpg	308	<B><I>Pinus flexilis</i> female cones</b> from second and third year of maturation. The resinous cones are characteristic of limber pine, taken at 8500 ft in Arizona.	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-229	16-229-t.jpg	16-229-v.jpg	60	16-229-h.jpg	210	<B><I>Pinus flexilis</i> female cones</b> from second year of growth, near the time of fertilization. Seed is shed at the end of the third year.	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-230	16-230-t.jpg	16-230-v.jpg	51	16-230-h.jpg	230	<B><I>Pinus contorta</i> male cones</b>. These are characteristic of late spring and are rapidly shed upon pollen shedding.	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-231	16-231-t.jpg	16-231-v.jpg	160	16-231-h.jpg	291	<B><I>Pinus ponderosa</i> trees</b> are sometimes  pioneering species in the Bonita lava field of Sunset Crater in Flagstaff, Arizona.	Coniferophyta, Coniferales, Pinaceae, habit, ecology		Lab20
16-232	16-232-t.jpg	16-232-v.jpg	224	16-232-h.jpg	410	<B><I>Pinus ponderosa</i> trees</b> showing mid-life growth form on the left, and crown senescence on the right, a typical sign of old age. Note extensive lateral dominance.	Coniferophyta, Coniferales, Pinaceae, habit, ecology		Lab20
16-233	16-233-t.jpg	16-233-v.jpg	217	16-233-h.jpg	393	<B><I>Pinus ponderosa</i> habit</b> shows increasing lateral dominance at a mature age.	Coniferophyta, Coniferales, Pinaceae, habit, ecology		Lab20
16-233	16-233a-t.jpg	16-233a-v.jpg	34	16-233a-h.jpg	116	<B><I>Podocarpus macrophyllous</i> seed</b> with subtending epimatium and characteristic strap-shaped leaves of the Podocarpaceae.	Coniferophyta, Coniferales, Podocarpaceae, reproductive		Lab20
16-234	16-234-t.jpg	16-234-v.jpg	192	16-234-h.jpg	350	<B><I>Pinus ponderosa</i> needle fall</b> typically occurs during the autumn, as with angiosperms, but only the oldest flush of needles falls.	Coniferophyta, Coniferales, Pinaceae, vegetative, ecology		Lab20
16-234	16-234a-t.jpg	16-234a-v.jpg	40	16-234a-h.jpg	150	<B><I>Podocarpus macrophyllous</i> seed</b> with subtending epimatium and characteristic strap-shaped leaves of the Podocarpaceae.	Coniferophyta, Coniferales, Podocarpaceae, reproductive		Lab21
16-235	16-235-t.jpg	16-235-v.jpg	59	16-235-h.jpg	243	<B><I>Pinus contorta</i> female cones</b> at seed shedding stage. Notice both closed and open scales.	Coniferophyta, Coniferales, Cupressaceae, reproductive		Lab21
16-236	16-236-t.jpg	16-236-v.jpg	60	16-236-h.jpg	221	<B><I>Agathis australis</i> male cones</b>, taken in Wellington, New Zealand.	Coniferophyta, Coniferales, Araucariaceae, reproductive		Lab21
16-237	16-237-t.jpg	16-237-v.jpg	226	16-237-h.jpg	379	<B><I>Agathis australis</i> female cones</b>, taken in Wellington, New Zealand.	Coniferophyta, Coniferales, Araucariaceae, reproductive		Lab21
16-238	16-238-t.jpg	16-238-v.jpg	239	16-238-h.jpg	417	<B><I>Agathis australis</i> habit</b>, taken in Wellington, New Zealand.	Coniferophyta, Coniferales, Araucariaceae, vegetative		Lab20
16-239	16-239-t.jpg	16-239-v.jpg	59	16-239-h.jpg	246	<B><I>Araucaria cunninghamii</i></b> in Cunungra, Queensland, Australia, showing whorled branching and juvenile form.	Coniferophyta, Coniferales, Araucariaceae, vegetative		Lab20
16-240	16-240-t.jpg	16-240-v.jpg	193	16-240-h.jpg	341	<B><I>Araucaria imbricata</i></b> in Lugano, showing whorled branching and strong apical dominance.	Coniferophyta, Coniferales, Araucariaceae, vegetative		Lab20
16-241	16-241-t.jpg	16-241-v.jpg	175	16-241-h.jpg	310	<B><I>Araucaria cunninghamii</i></b> in Queensland, Australia, showing whorled branching of both juvenile and adult forms.	Coniferophyta, Coniferales, Araucariaceae, vegetative		Lab20
16-242	16-242-t.jpg	16-242-v.jpg	158	16-242-h.jpg	290	<B><I>Bunya</i></b> in Cunungra, Queensland, Australia, showing whorled branching and juvenile form.	Coniferophyta, Coniferales, Araucariaceae, vegetative		Lab20
16-420	16-420-t.jpg	16-420-v.jpg	176	16-420-h.jpg	310	<B><I>Pinus</i> bisexual strobilus</b> in median longitudinal section (microscope slide prepared by Frank Reinhart).	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-421	16-421-t.jpg	16-421-v.jpg	64	16-421-h.jpg	234	<B><I>Pinus</i> bisexual strobilus</b> with basal pollen producing region and apical ovuliferous scales.	Coniferophyta, Coniferales, Pinaceae, reproductive		Lab21
16-422	16-422-t.jpg	16-422-v.jpg	46	16-422-h.jpg	212	<B><I>Pinus</i> embryogenesis</b> showing embryos isolated from a single megagametophyte. These include cleavage products of sexually-dervied embryos.	Coniferophyta, Coniferales, Pinaceae, reproductive, embryogenesis		Lab21
16-423	16-423-t.jpg	16-423-v.jpg	76	16-423-h.jpg	275	<B><I>Pinus</i> embryogenesis</b> during elongation of the suspensor and embryonal tiers.	Coniferophyta, Coniferales, Pinaceae, reproductive, embryogenesis		Lab21
16-424	16-424-t.jpg	16-424-v.jpg	68	16-424-h.jpg	249	<B><I>Pinus</i> early embryogenesis</b> showing four free nuclei in dense cytoplasmic region at the base of the zygote.	Coniferophyta, Coniferales, Pinaceae, reproductive, embryogenesis		Lab21
16-425	16-425-t.jpg	16-425-v.jpg	27	16-425-h.jpg	149	<B><I>Pinus</i> fertilization</b> with mitotic method of fusion (male and female nuclear material remains separate until the onset of mitotic division).	Coniferophyta, Coniferales, Pinaceae, reproductive, embryogenesis		Lab21
16-426	16-426-t.jpg	16-426-v.jpg	93	16-426-h.jpg	331	<B><I>Pinus</i> pollen tubes</b> elongating in the nucellus. Egg is present in the archegonium.	Coniferophyta, Coniferales, Pinaceae, reproductive, embryogenesis		Lab21
16-427	16-427-t.jpg	16-427-v.jpg	66	16-427-h.jpg	247	<B><I>Pinus</i> archegonia</b> in a maturing megagametophyte.	Coniferophyta, Coniferales, Pinaceae, reproductive, megagametogenesis		Lab21
16-428	16-428-t.jpg	16-428-v.jpg	77	16-428-h.jpg	296	<B><I>Pinus</i> ovule with pollen tube</b> in the nucellus and an archegonium just beneath archegonial chamber.	Coniferophyta, Coniferales, Pinaceae, reproductive, megagametogenesis		Lab21
16-429	16-429-t.jpg	16-429-v.jpg	98	16-429-h.jpg	355	<B><I>Pinus</i> ovule with pollen tube</b> in the nucellus. At this stage, free-nuclear division has just begun during early megagametogenesis.	Coniferophyta, Coniferales, Pinaceae, reproductive, megagametogenesis		Lab21
16-430	16-430-t.jpg	16-430-v.jpg	100	16-430-h.jpg	350	<B><I>Pinus</i> ovule with pollen tube</b> in the nucellus. Pollination has already occurred, as indicated by pollen grain lodged at base of the micropyle.	Coniferophyta, Coniferales, Pinaceae, reproductive, megasporogenesis		Lab21
16-431	16-431-t.jpg	16-431-v.jpg	107	16-431-h.jpg	369	<B><I>Pinus</i> ovuliferous scale</b> with a megasporocyte (megaspore mother cell) at the center of the nuclellus.  Note scale, bract and ovule orientation.	Coniferophyta, Coniferales, Pinaceae, reproductive, megagametogenesis		Lab21